Last updated: April 15, 2024
Publications
Title | Authors | Year | Citation |
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Increasing large wildfires over the western United States linked to diminishing sea ice in the Arctic | Y. Zou, P. J. Rasch, H. Wang, Z. Xie, R. Zhang | 2021 | Zou, Y., Rasch, P.J., Wang, H., Xie, Z., and Zhang, R., 2021, Increasing large wildfires over the western United States linked to diminishing sea ice in the Arctic: Nature Communications, v. 12, no. 1, article 6048, at https://doi.org/10.1038/s41467-021-26232-9. |
Quantifying contributions of natural variability and anthropogenic forcings on increased fire weather risk over the western United States | Y. Zhuang, R. Fu, B. D. Santer, R. E. Dickinson, A. Hall | 2021 | Zhuang, Y., Fu, R., Santer, B.D., Dickinson, R.E., and Hall, A., 2021, Quantifying contributions of natural variability and anthropogenic forcings on increased fire weather risk over the western United States: Proceedings of the National Academy of Sciences of the United States of America, v. 118, no. 45, article e2111875118, at https://doi.org/10.1073/pnas.2111875118. |
Remote sensing of land change—A multifaceted perspective | Z. Zhu, S. Qiu, S. Ye | 2022 | Zhu, Z., Qiu, S., and Ye, S., 2022, Remote sensing of land change—A multifaceted perspective: Remote Sensing of Environment, v. 282, article 113266, at https://doi.org/10.1016/j.rse.2022.113266. |
Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the United States | Zhu, Z., ed.,, Bouchard, M., Butman, D., Hawbaker, T., Li, Z., Liu, J., Liu, S., McDonald, C., Reker, R., Sayler, K., Sleeter, B., Sohl, T., Stackpoole, S., Wein, A., Zhu, Z. | 2011 | Zhu, Z., ed.,, Bouchard, M., Butman, D., Hawbaker, T., Li, Z., Liu, J., Liu, S., McDonald, C., Reker, R., et al., 2011, Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the United States: Reston, Va., U.S. Geological Survey Professional Paper 1787, 40 p., at https://doi.org/10.3133/pp1787. |
Beyond biomass to carbon fluxes—Application and evaluation of a comprehensive Forest Carbon Monitoring System | Y. Zhou, C. A. Williams, N. Hasler, H. Gu, R. E. Kennedy | 2021 | Zhou, Y., Williams, C.A., Hasler, N., Gu, H., and Kennedy, R.E., 2021, Beyond biomass to carbon fluxes—Application and evaluation of a comprehensive Forest Carbon Monitoring System: Environmental Research Letters, v. 16, no. 5, article 055026, at https://doi.org/10.1088/1748-9326/abf06d. |
Forecasting timber, biomass, and tree carbon pools with the output of state and transition models | Zhou, X., Hemstrom, M.A. | 2012 | Zhou, X., and Hemstrom, M.A., 2012, Forecasting timber, biomass, and tree carbon pools with the output of state and transition models, in First Landscape State-and-Transition Simulation Modeling Conference, Portland, Oreg., 14–16 June 2011, Proceedings, General Technical Report PNW-GTR-869: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, p. 115–121, at https://www.treesearch.fs.fed.us/pubs/42567. |
Monitoring landscape dynamics in central U.S. grasslands with harmonized Landsat-8 and Sentinel-2 time series data | Q. Zhou, J. Rover, J. Brown, B. Worstell, D. Howard, Z. Wu, A. L. Gallant, B. Rundquist, M. Burke | 2019 | Zhou, Q., Rover, J., Brown, J., Worstell, B., Howard, D., Wu, Z., Gallant, A.L., Rundquist, B., and Burke, M., 2019, Monitoring landscape dynamics in central U.S. grasslands with harmonized Landsat-8 and Sentinel-2 time series data: Remote Sensing, v. 11, no. 3, article 328, at https://doi.org/10.3390/rs11030328. |
Methods of rapid quality assessment for national-scale land surface change monitoring | Q. Zhou, C. Barber, G. Xian | 2020 | Zhou, Q., Barber, C., and Xian, G., 2020, Methods of rapid quality assessment for national-scale land surface change monitoring: Remote Sensing, v. 12, no. 16, article 2524, at https://doi.org/10.3390/rs12162524. |
Synoptic weather patterns for large wildfires in the northwestern United States—A climatological analysis using three classification methods | S. Zhong, L. Yu, W. E. Heilman, X. Bian, H. Fromm | 2020 | Zhong, S., Yu, L., Heilman, W.E., Bian, X., and Fromm, H., 2020, Synoptic weather patterns for large wildfires in the northwestern United States—A climatological analysis using three classification methods: Theoretical and Applied Climatology, v. 141, no. 3-4, p. 1057–1073, at https://doi.org/10.1007/s00704-020-03235-y. |
A new burn severity index based on land surface temperature and enhanced vegetation index | Z. Zheng, Y. Zeng, S. Li, W. Huang | 2016 | Zheng, Z., Zeng, Y., Li, S., and Huang, W., 2016, A new burn severity index based on land surface temperature and enhanced vegetation index: International Journal of Applied Earth Observation and Geoinformation, v. 45, p. 84–94, at https://doi.org/10.1016/j.jag.2015.11.002. |
Forest fire spread simulating model using cellular automaton with extreme learning machine | Z. Zheng, W. Huang, S. Li, Y. Zeng | 2017 | Zheng, Z., Huang, W., Li, S., and Zeng, Y., 2017, Forest fire spread simulating model using cellular automaton with extreme learning machine: Ecological Modelling, v. 348, p. 33–43, at https://doi.org/10.1016/j.ecolmodel.2016.12.022. |
Forest carbon dynamics associated with growth and disturbances in Oklahoma and Texas, 1992–2006 | D. Zheng, L. S. Heath, M. J. Ducey, J. E. Smith | 2013 | Zheng, D., Heath, L.S., Ducey, M.J., and Smith, J.E., 2013, Forest carbon dynamics associated with growth and disturbances in Oklahoma and Texas, 1992–2006: Southern Journal of Applied Forestry, v. 37, no. 4, p. 216–225, at https://doi.org/10.5849/sjaf.12-028. |
Carbon changes in conterminous US forests associated with growth and major disturbances—1992–2001 | D. Zheng, L. S. Heath, M. J. Ducey, J. E. Smith | 2011 | Zheng, D., Heath, L.S., Ducey, M.J., and Smith, J.E., 2011, Carbon changes in conterminous US forests associated with growth and major disturbances—1992–2001: Environmental Research Letters, v. 6, no. 1, article 014012, at https://doi.org/10.1088/1748-9326/6/1/014012. |
Assessing double counting of carbon emissions between forest land-cover change and forest wildfires—A case study in the United States, 1992–2006 | D. Zheng, L. S. Heath, M. J. Ducey, B. Quayle | 2013 | Zheng, D., Heath, L.S., Ducey, M.J., and Quayle, B., 2013, Assessing double counting of carbon emissions between forest land-cover change and forest wildfires—A case study in the United States, 1992–2006: Ecosystems, v. 16, no. 2, p. 310–322, at https://doi.org/10.1007/s10021-012-9616-1. |
Monthly mapping of forest harvesting using dense time series Sentinel-1 SAR imagery and deep learning | F. Zhao, R. Sun, L. Zhong, R. Meng, C. Huang, X. Zeng, M. Wang, Y. Li, Z. Wang | 2022 | Zhao, F., Sun, R., Zhong, L., Meng, R., Huang, C., Zeng, X., Wang, M., Li, Y., and Wang, Z., 2022, Monthly mapping of forest harvesting using dense time series Sentinel-1 SAR imagery and deep learning: Remote Sensing of Environment, v. 269, article 112822, at https://doi.org/10.1016/j.rse.2021.112822. |
Comparing historical and current wildfire regimes in the Northern Rocky Mountains using a landscape succession model | F. Zhao, R. Keane, Z. Zhu, C. Huang | 2015 | Zhao, F., Keane, R., Zhu, Z., and Huang, C., 2015, Comparing historical and current wildfire regimes in the Northern Rocky Mountains using a landscape succession model: Forest Ecology and Management, v. 343, p. 9–21, at https://doi.org/10.1016/j.foreco.2015.01.020. |
Use of vegetation change tracker and support vector machine to map disturbance types in Greater Yellowstone ecosystems in a 1984–2010 Landsat time series | F. Zhao, C. Q. Huang, Z. L. Zhu | 2015 | Zhao, F., Huang, C.Q., and Zhu, Z.L., 2015, Use of vegetation change tracker and support vector machine to map disturbance types in Greater Yellowstone ecosystems in a 1984–2010 Landsat time series: IEEE Geoscience and Remote Sensing Letters, v. 12, no. 8, p. 1650–1654, at https://doi.org/10.1109/lgrs.2015.2418159. |
Biophysical feedback of forest canopy height on land surface temperature over contiguous United States | Z. Zhang, X. Li, H. Liu | 2021 | Zhang, Z., Li, X., and Liu, H., 2021, Biophysical feedback of forest canopy height on land surface temperature over contiguous United States: Environmental Research Letters, v. 17, no. 3, article 034002, at https://doi.org/10.1088/1748-9326/ac4657. |
Land cover change-induced decline in terrestrial gross primary production over the conterminous United States from 2001 to 2016 | Y. Zhang, C. Song, T. Hwang, K. Novick, J. W. Coulston, J. Vose, M. P. Dannenberg, C. R. Hakkenberg, J. Mao, C. E. Woodcock | 2021 | Zhang, Y., Song, C., Hwang, T., Novick, K., Coulston, J.W., Vose, J., Dannenberg, M.P., Hakkenberg, C.R., Mao, J., and Woodcock, C.E., 2021, Land cover change-induced decline in terrestrial gross primary production over the conterminous United States from 2001 to 2016: Agricultural and Forest Meteorology, v. 308-309, article 108609, at https://doi.org/10.1016/j.agrformet.2021.108609. |
Interannual variation in biomass burning and fire seasonality derived from geostationary satellite data across the contiguous United States from 1995 to 2011 | X. Zhang, S. Kondragunta, D. P. Roy | 2014 | Zhang, X., Kondragunta, S., and Roy, D.P., 2014, Interannual variation in biomass burning and fire seasonality derived from geostationary satellite data across the contiguous United States from 1995 to 2011: Journal of Geophysical Research—Biogeosciences, v. 119, no. 6, article 2013JG002518, at https://doi.org/10.1002/2013JG002518. |
Estimation of biomass burned areas using multiple-satellite-observed active fires | X. Zhang, S. Kondragunta, B. Quayle | 2011 | Zhang, X., Kondragunta, S., and Quayle, B., 2011, Estimation of biomass burned areas using multiple-satellite-observed active fires: IEEE Transactions on Geoscience and Remote Sensing, v. 49, no. 11, pt. 2, p. 4469–4482, at https://doi.org/10.1109/TGRS.2011.2149535. |
Large wildfires in the western United States exacerbated by tropospheric drying linked to a multi-decadal trend in the expansion of the Hadley Circulation | L. Zhang, W. Lau, W. Tao, Z. Li | 2020 | Zhang, L., Lau, W., Tao, W., and Li, Z., 2020, Large wildfires in the western United States exacerbated by tropospheric drying linked to a multi-decadal trend in the expansion of the Hadley Circulation: Geophysical Research Letters, v. 47, no. 16, article e2020GL087911, at https://doi.org/10.1029/2020GL087911. |
Attributing carbon changes in conterminous U.S. forests to disturbance and non-disturbance factors from 1901 to 2010 | F. Zhang, J. M. Chen, Y. Pan, R. A. Birdsey, S. Shen, W. Ju, L. He | 2012 | Zhang, F., Chen, J.M., Pan, Y., Birdsey, R.A., Shen, S., Ju, W., and He, L., 2012, Attributing carbon changes in conterminous U.S. forests to disturbance and non-disturbance factors from 1901 to 2010: Journal of Geophysical Research—Biogeosciences, v. 117, no. 2, article G02021, at https://doi.org/10.1029/2011JG001930. |
Impacts of inadequate historical disturbance data in the early twentieth century on modeling recent carbon dynamics (1951–2010) in conterminous U.S. forests | F. Zhang, J. M. Chen, Y. Pan, R. A. Birdsey, S. Shen, W. Ju, A. J. Dugan | 2015 | Zhang, F., Chen, J.M., Pan, Y., Birdsey, R.A., Shen, S., Ju, W., and Dugan, A.J., 2015, Impacts of inadequate historical disturbance data in the early twentieth century on modeling recent carbon dynamics (1951–2010) in conterminous U.S. forests: Journal of Geophysical Research—Biogeosciences, v. 120, no. 3, article 2014JG002798, at https://doi.org/10.1002/2014JG002798. |
Duff burning from wildfires in a moist region—Different impacts on PM2.5 and ozone | A. Zhang, Y. Liu, S. Goodrick, M. D. Williams | 2022 | Zhang, A., Liu, Y., Goodrick, S., and Williams, M.D., 2022, Duff burning from wildfires in a moist region—Different impacts on PM2.5 and ozone: Atmospheric Chemistry and Physics, v. 22, no. 1, p. 597–624, at https://doi.org/10.5194/acp-22-597-2022. |
Wildfire susceptibility of land use and topographic features in the western United States—Implications for the landscape management | J. Zhai, Z. Ning, R. Dahal, S. Yang | 2023 | Zhai, J., Ning, Z., Dahal, R., and Yang, S., 2023, Wildfire susceptibility of land use and topographic features in the western United States—Implications for the landscape management: Forests, v. 14, no. 4, article 807, at https://doi.org/10.3390/f14040807. |
A system for burned area detection on multispectral imagery | M. Zanetti, S. Saha, D. Marinelli, M. L. Magliozzi, M. Zavagli, M. Costantini, F. Bovolo, L. Bruzzone | 2022 | Zanetti, M., Saha, S., Marinelli, D., Magliozzi, M.L., Zavagli, M., Costantini, M., Bovolo, F., and Bruzzone, L., 2022, A system for burned area detection on multispectral imagery: IEEE Transactions on Geoscience and Remote Sensing, v. 60, article 5404315, at https://doi.org/10.1109/tgrs.2021.3110280. |
A novel digital twin architecture with similarity-based hybrid modeling for supporting dependable disaster management systems | S. J. Yun, J. W. Kwon, W. T. Kim | 2022 | Yun, S.J., Kwon, J.W., and Kim, W.T., 2022, A novel digital twin architecture with similarity-based hybrid modeling for supporting dependable disaster management systems: Sensors, v. 22, no. 13, article 4774, at https://doi.org/10.3390/s22134774. |
Process?based quantification of the role of wildfire in shaping flood frequency | G. Yu, T. Liu, L. A. McGuire, D. B. Wright, B. J. Hatchett, J. J. Miller, M. Berli, J. Giovando, M. Bartles, I. E. Floyd | 2023 | Yu, G., Liu, T., McGuire, L.A., Wright, D.B., Hatchett, B.J., Miller, J.J., Berli, M., Giovando, J., Bartles, M., and Floyd, I.E., 2023, Process?based quantification of the role of wildfire in shaping flood frequency: Water Resources Research, v. 59, no. 12, article e2023WR035013, at https://doi.org/10.1029/2023wr035013. |
Performance of fire danger indices and their utility in predicting future wildfire danger over the conterminous United States | G. Yu, Y. Feng, J. Wang, D. B. Wright | 2023 | Yu, G., Feng, Y., Wang, J., and Wright, D.B., 2023, Performance of fire danger indices and their utility in predicting future wildfire danger over the conterminous United States: Earth's Future, v. 11, no. 11, article e2023EF003823, at https://doi.org/10.1029/2023ef003823. |
Modeling the impact of climate change and wildfire on the Dusky Grouse (Dendragapus obscurus) in the American Southwest—Implications for conservation | J. Youtz, R. Goljani Amirkhiz, J. K. Frey | 2022 | Youtz, J., Goljani Amirkhiz, R., and Frey, J.K., 2022, Modeling the impact of climate change and wildfire on the Dusky Grouse (Dendragapus obscurus) in the American Southwest—Implications for conservation: Avian Conservation and Ecology, v. 17, no. 1, article 35, at https://doi.org/10.5751/ace-02222-170135. |
Using wildfire as a management strategy to restore resiliency to ponderosa pine forests in the southwestern United States | J. D. Young, A. A. Ager, A. E. Thode | 2022 | Young, J.D., Ager, A.A., and Thode, A.E., 2022, Using wildfire as a management strategy to restore resiliency to ponderosa pine forests in the southwestern United States: Ecosphere, v. 13, no. 5, article e4040, at https://doi.org/10.1002/ecs2.4040. |
Resource objective wildfire leveraged to restore old growth forest structure while stabilizing carbon stocks in the southwestern United States | J. D. Young, A. A. Ager | 2024 | Young, J.D., and Ager, A.A., 2024, Resource objective wildfire leveraged to restore old growth forest structure while stabilizing carbon stocks in the southwestern United States: Ecological Modelling, v. 488, article 110573, at https://doi.org/10.1016/j.ecolmodel.2023.110573. |
Tundra fire increases the likelihood of methane hotspot formation in the Yukon-Kuskokwim Delta, Alaska, USA | E. Yoseph, E. Hoy, C. Elder, S. M. Ludwig, D. Thompson, C. E. Miller | 2023 | Yoseph, E., Hoy, E., Elder, C., Ludwig, S.M., Thompson, D., and Miller, C.E., 2023, Tundra fire increases the likelihood of methane hotspot formation in the Yukon-Kuskokwim Delta, Alaska, USA: Environmental Research Letters, v. 18, no. 10, article 104042, at https://doi.org/10.1088/1748-9326/acf50b. |
Fire severity in reburns depends on vegetation type in Arizona and New Mexico, U.S.A. | L. L. Yocom, J. Jenness, P. Z. Fulé, A. E. Thode | 2022 | Yocom, L.L., Jenness, J., Fulé, P.Z., and Thode, A.E., 2022, Fire severity in reburns depends on vegetation type in Arizona and New Mexico, U.S.A.: Forests, v. 13, no. 11, article 1957, at https://doi.org/10.3390/f13111957. |
Previous fires and roads limit wildfire growth in Arizona and New Mexico, U.S.A. | L. L. Yocom, J. Jenness, P. Z. Fulé, A. E. Thode | 2019 | Yocom, L.L., Jenness, J., Fulé, P.Z., and Thode, A.E., 2019, Previous fires and roads limit wildfire growth in Arizona and New Mexico, U.S.A.: Forest Ecology and Management, v. 449, article 117440, at https://doi.org/10.1016/j.foreco.2019.06.037. |
Wildfire risk and urban expansion in South Kohala and North Kona, Hawaiʻi—Assessing new and existing areas of wildfire risk in relation to Hawaiʻi’s fire history, land cover, and tree canopy, through the lens of urban expansion | Yee, C. | 2024 | Yee, C., 2024, Wildfire risk and urban expansion in South Kohala and North Kona, Hawaiʻi—Assessing new and existing areas of wildfire risk in relation to Hawaiʻi’s fire history, land cover, and tree canopy, through the lens of urban expansion: Kaulunani, Hawaiʻi, Kaulunani Urban and Community Forestry Program of the DLNR Division of Forestry and Wildlife, and State and Private Forestry, branch of the U.S. Forest Service, Region 5 Technical Report, 17 p., at https://dlnr.hawaii.gov/forestry/files/2024/03/Yee_TechnicalReport.pdf. |
A new generation of the United States National Land Cover Database—Requirements, research priorities, design, and implementation strategies | L. Yang, S. Jin, P. Danielson, C. Homer, L. Gass, S. M. Bender, A. Case, C. Costello, J. Dewitz, J. Fry, M. Funk, B. Granneman, G. C. Liknes, M. Rigge, G. Xian | 2018 | Yang, L., Jin, S., Danielson, P., Homer, C., Gass, L., Bender, S.M., Case, A., Costello, C., Dewitz, J., et al., 2018, A new generation of the United States National Land Cover Database—Requirements, research priorities, design, and implementation strategies: ISPRS Journal of Photogrammetry and Remote Sensing, v. 146, p. 108–123, at https://doi.org/10.1016/j.isprsjprs.2018.09.006. |
Fire modulates climate change response of simulated aspen distribution across topoclimatic gradients in a semi-arid montane landscape | J. Yang, P. Weisberg, D. Shinneman, T. Dilts, S. Earnst, R. Scheller | 2015 | Yang, J., Weisberg, P., Shinneman, D., Dilts, T., Earnst, S., and Scheller, R., 2015, Fire modulates climate change response of simulated aspen distribution across topoclimatic gradients in a semi-arid montane landscape: Landscape Ecology, v. 30, no. 6, p. 1055–1073, at https://doi.org/10.1007/s10980-015-0160-1. |
A growing importance of large fires in conterminous United States during 1984–2012 | J. Yang, H. Tian, B. Tao, W. Ren, S. Pan, Y. Liu, Y. Wang | 2015 | Yang, J., Tian, H., Tao, B., Ren, W., Pan, S., Liu, Y., and Wang, Y., 2015, A growing importance of large fires in conterminous United States during 1984–2012: Journal of Geophysical Research—Biogeosciences, v. 120, no. 12, p. 2625–2640, at https://doi.org/10.1002/2015JG002965. |
Continental-scale quantification of post-fire vegetation greenness recovery in temperate and boreal North America | J. Yang, S. Pan, S. Dangal, B. Zhang, S. Wang, H. Tian | 2017 | Yang, J., Pan, S., Dangal, S., Zhang, B., Wang, S., and Tian, H., 2017, Continental-scale quantification of post-fire vegetation greenness recovery in temperate and boreal North America: Remote Sensing of Environment, v. 199, p. 277–290, at https://doi.org/10.1016/j.rse.2017.07.022. |
Wildfire burn severity and emissions inventory—An example implementation over California | Q. Xu, A. L. Westerling, A. Notohamiprodjo, C. Wiedinmyer, J. J. Picotte, S. A. Parks, M. D. Hurteau, M. E. Marlier, C. A. Kolden, J. A. Sam, W. J. Baldwin, C. Ade | 2022 | Xu, Q., Westerling, A.L., Notohamiprodjo, A., Wiedinmyer, C., Picotte, J.J., Parks, S.A., Hurteau, M.D., Marlier, M.E., Kolden, C.A., et al., 2022, Wildfire burn severity and emissions inventory—An example implementation over California: Environmental Research Letters, v. 17, no. 8, article 085008, at https://doi.org/10.1088/1748-9326/ac80d0. |
Spatial and temporal patterns of wildfire burn severity and biomass burning-induced emissions in California | Q. Xu, A. L. Westerling, W. J. Baldwin | 2022 | Xu, Q., Westerling, A.L., and Baldwin, W.J., 2022, Spatial and temporal patterns of wildfire burn severity and biomass burning-induced emissions in California: Environmental Research Letters, v. 17, article 115001, at https://doi.org/10.1088/1748-9326/ac9704. |
Remote sensing of the terrestrial carbon cycle—A review of advances over 50 years | J. Xiao, F. Chevallier, C. Gomez, L. Guanter, J. A. Hicke, A. R. Huete, K. Ichii, W. Ni, Y. Pang, A. F. Rahman, G. Sun, W. Yuan, L. Zhang, X. Zhang | 2019 | Xiao, J., Chevallier, F., Gomez, C., Guanter, L., Hicke, J.A., Huete, A.R., Ichii, K., Ni, W., Pang, Y., et al., 2019, Remote sensing of the terrestrial carbon cycle—A review of advances over 50 years: Remote Sensing of Environment, v. 233, article 111383, at https://doi.org/10.1016/j.rse.2019.111383. |
Effects of land cover and regional climate variations on long-term spatiotemporal changes in sagebrush ecosystems | G. Xian, C. Homer, C. Aldridge | 2012 | Xian, G., Homer, C., and Aldridge, C., 2012, Effects of land cover and regional climate variations on long-term spatiotemporal changes in sagebrush ecosystems: GIScience & Remote Sensing, v. 49, no. 3, p. 378–396, at https://doi.org/10.2747/1548-1603.49.3.378. |
Ecosystem performance monitoring of rangelands by integrating modeling and remote sensing | B. K. Wylie, S. P. Boyte, D. J. Major | 2012 | Wylie, B.K., Boyte, S.P., and Major, D.J., 2012, Ecosystem performance monitoring of rangelands by integrating modeling and remote sensing: Rangeland Ecology & Management, v. 65, no. 3, p. 241–252, at https://doi.org/10.2111/Rem-D-11-00058.1. |
Low-intensity fires mitigate the risk of high-intensity wildfires in California’s forests | X. Wu, E. Sverdrup, M. D. Mastrandrea, M. W. Wara, W. Wager | 2023 | Wu, X., Sverdrup, E., Mastrandrea, M.D., Wara, M.W., and Wager, W., 2023, Low-intensity fires mitigate the risk of high-intensity wildfires in California’s forests: Science Advances, v. 9, no. 45, article eadi4123 at https://doi.org/10.1126/sciadv.adi4123. |
Spatially explicit models of seed availability improve predictions of conifer regeneration following the 2018 Carr Fire in northern California | M. Wright, P. van Mantgem, K. Buffington, K. Thorne, E. Engber, S. Smith | 2023 | Wright, M., van Mantgem, P., Buffington, K., Thorne, K., Engber, E., and Smith, S., 2023, Spatially explicit models of seed availability improve predictions of conifer regeneration following the 2018 Carr Fire in northern California: Frontiers in Ecology and Evolution, v. 11, article 1229123, at https://doi.org/10.3389/fevo.2023.1229123. |
Extent of recent fire-induced losses of ponderosa pine forests of Arizona and New Mexico, USA | A. M. Woolman, J. D. Coop, J. D. Shaw, J. DeMarco | 2022 | Woolman, A.M., Coop, J.D., Shaw, J.D., and DeMarco, J., 2022, Extent of recent fire-induced losses of ponderosa pine forests of Arizona and New Mexico, USA: Forest Ecology and Management, v. 520, article 120381, at https://doi.org/10.1016/j.foreco.2022.120381. |
A bird's eye view of ecosystem conversion—Examining the resilience of piñon-juniper woodlands and their avian communities in the face of fire regime change | J. Woolet, C. S. Stevens-Rumann, J. D. Coop, L. Pejchar | 2023 | Woolet, J., Stevens-Rumann, C.S., Coop, J.D., and Pejchar, L., 2023, A bird's eye view of ecosystem conversion—Examining the resilience of piñon-juniper woodlands and their avian communities in the face of fire regime change: Forest Ecology and Management, v. 546, article 121368, at https://doi.org/10.1016/j.foreco.2023.121368. |
Abducted by avians—The presence of avifauna in piñon-juniper woodlands in the post-fire environment, Final Report | Woolet, J., Stevens-Rumann, C. | 2022 | Woolet, J., and Stevens-Rumann, C., 2022, Abducted by avians—The presence of avifauna in piñon-juniper woodlands in the post-fire environment, Final Report: Joint Fire Science Program JFSP PROJECT ID—21-1-01-36, 40 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%27%3AV%20%20%20%0A. |
Early postfire response of a northern range margin coast redwood forest community | B. D. Woodward, W. H. Romme, P. H. Evangelista | 2020 | Woodward, B.D., Romme, W.H., and Evangelista, P.H., 2020, Early postfire response of a northern range margin coast redwood forest community: Forest Ecology and Management, v. 462, article 117966, at https://doi.org/10.1016/j.foreco.2020.117966. |
Fire and development influences on sagebrush community plant groups across a climate gradient in northern Nevada | D. J. A. Wood, T. Seipel, K. M. Irvine, L. J. Rew, P. C. Stoy | 2019 | Wood, D.J.A., Seipel, T., Irvine, K.M., Rew, L.J., and Stoy, P.C., 2019, Fire and development influences on sagebrush community plant groups across a climate gradient in northern Nevada: Ecosphere, v. 10, no. 12, article e02990, at https://doi.org/10.1002/ecs2.2990. |
Sensitivity analysis on distance-adjusted propensity score matching for wildfire effect quantification using national forest inventory data | H. Woo, B. N. I. Eskelson, V. J. Monleon | 2021 | Woo, H., Eskelson, B.N.I., and Monleon, V.J., 2021, Sensitivity analysis on distance-adjusted propensity score matching for wildfire effect quantification using national forest inventory data: Environmental Modelling & Software, v. 144, article 105163, at https://doi.org/10.1016/j.envsoft.2021.105163. |
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A 25-year history of spatial and temporal trends in wildfire activity in Oregon and Washington, U.S.A. | M. G. Wing, J. Long | 2015 | Wing, M.G., and Long, J., 2015, A 25-year history of spatial and temporal trends in wildfire activity in Oregon and Washington, U.S.A.: Modern Applied Science, v. 9, no. 3, p. 117–132, at https://doi.org/10.5539/mas.v9n3p117. |
Nonlinear long-term large watershed hydrologic response to wildfire and climatic dynamics locally increases water yields | M. L. Wine, O. Makhnin, D. Cadol | 2018 | Wine, M.L., Makhnin, O., and Cadol, D., 2018, Nonlinear long-term large watershed hydrologic response to wildfire and climatic dynamics locally increases water yields: Earth's Future, v. 6, no. 7, p. 997–1006, at https://doi.org/10.1029/2018ef000930. |
In ecoregions across western USA streamflow increases during post-wildfire recovery | M. L. Wine, D. Cadol, O. Makhnin | 2018 | Wine, M.L., Cadol, D., and Makhnin, O., 2018, In ecoregions across western USA streamflow increases during post-wildfire recovery: Environmental Research Letters, v. 13, no. 1, article 014010, at https://doi.org/10.1088/1748-9326/aa9c5a. |
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Expanding number of western US urban centers face declining summertime air quality due to enhanced wildland fire activity | T. Y. Wilmot, A. G. Hallar, J. C. Lin, D. V. Mallia | 2021 | Wilmot, T.Y., Hallar, A.G., Lin, J.C., and Mallia, D.V., 2021, Expanding number of western US urban centers face declining summertime air quality due to enhanced wildland fire activity: Environmental Research Letters, v. 16, no. 5, article 054036, at https://doi.org/10.1088/1748-9326/abf966. |
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Correlations between components of the water balance and burned area reveal new insights for predicting forest fire area in the southwest United States | A. P. Williams, R. Seager, A. K. MacAlady, M. Berkelhammer, M. A. Crimmins, T. W. Swetnam, A. T. Trugman, N. Buenning, D. Noone, N. G. McDowell, N. Hryniw, C. I. Mora, T. Rahn | 2015 | Williams, A.P., Seager, R., MacAlady, A.K., Berkelhammer, M., Crimmins, M.A., Swetnam, T.W., Trugman, A.T., Buenning, N., Noone, D., et al., 2015, Correlations between components of the water balance and burned area reveal new insights for predicting forest fire area in the southwest United States: International Journal of Wildland Fire, v. 24, no. 1, p. 14–26, at https://doi.org/10.1071/WF14023. |
Growing impact of wildfire on western US water supply | A. P. Williams, B. Livneh, K. A. McKinnon, W. D. Hansen, J. S. Mankin, B. I. Cook, J. E. Smerdon, A. M. Varuolo-Clarke, N. R. Bjarke, C. S. Juang, D. P. Lettenmaier | 2022 | Williams, A.P., Livneh, B., McKinnon, K.A., Hansen, W.D., Mankin, J.S., Cook, B.I., Smerdon, J.E., Varuolo-Clarke, A.M., Bjarke, N.R., et al., 2022, Growing impact of wildfire on western US water supply: Proceedings of the National Academy of Sciences of the United States of America, v. 119, no. 10, article e2114069119, at https://doi.org/10.1073/pnas.2114069119. |
Effect of reduced summer cloud shading on evaporative demand and wildfire in coastal southern California | A. P. Williams, P. Gentine, M. A. Moritz, D. A. Roberts, J. T. Abatzoglou | 2018 | Williams, A.P., Gentine, P., Moritz, M.A., Roberts, D.A., and Abatzoglou, J.T., 2018, Effect of reduced summer cloud shading on evaporative demand and wildfire in coastal southern California: Geophysical Research Letters, v. 45, no. 11, p. 5653–5662, at https://doi.org/10.1029/2018gl077319. |
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Multi-scale quantification of anthropogenic, fire, and drought-associated forest disturbances across the continental U.S., 2000–2014 | M. Wang, C. Xu, D. J. Johnson, C. D. Allen, M. Anderson, G. Wang, G. Qie, K. C. Solander, N. G. McDowell | 2022 | Wang, M., Xu, C., Johnson, D.J., Allen, C.D., Anderson, M., Wang, G., Qie, G., Solander, K.C., and McDowell, N.G., 2022, Multi-scale quantification of anthropogenic, fire, and drought-associated forest disturbances across the continental U.S., 2000–2014: Frontiers in Forests and Global Change, v. 5, article 693418, at https://doi.org/10.3389/ffgc.2022.693418. |
Investigation of wildfire impacts on land surface phenology from MODIS time series in the western US forests | J. M. Wang, X. Y. Zhang | 2020 | Wang, J.M., and Zhang, X.Y., 2020, Investigation of wildfire impacts on land surface phenology from MODIS time series in the western US forests: ISPRS Journal of Photogrammetry and Remote Sensing, v. 159, p. 281–295, at https://doi.org/10.1016/j.isprsjprs.2019.11.027. |
Land cover composition, climate, and topography drive land surface phenology in a recently burned landscape—An application of machine learning in phenological modeling | J. Wang, X. Zhang, K. Rodman | 2021 | Wang, J., Zhang, X., and Rodman, K., 2021, Land cover composition, climate, and topography drive land surface phenology in a recently burned landscape—An application of machine learning in phenological modeling: Agricultural and Forest Meteorology, v. 304-305, article 108432, at https://doi.org/10.1016/j.agrformet.2021.108432. |
Impacts of wildfires on interannual trends in land surface phenology—An investigation of the Hayman Fire | J. Wang, X. Zhang | 2017 | Wang, J., and Zhang, X., 2017, Impacts of wildfires on interannual trends in land surface phenology—An investigation of the Hayman Fire: Environmental Research Letters, v. 12, no. 5, article 054008, at https://doi.org/10.1088/1748-9326/aa6ad9. |
Characterizing the encroachment of juniper forests into sub-humid and semi-arid prairies from 1984 to 2010 using PALSAR and Landsat data | J. Wang, X. Xiao, Y. Qin, R. B. Doughty, J. Dong, Z. Zou | 2018 | Wang, J., Xiao, X., Qin, Y., Doughty, R.B., Dong, J., and Zou, Z., 2018, Characterizing the encroachment of juniper forests into sub-humid and semi-arid prairies from 1984 to 2010 using PALSAR and Landsat data: Remote Sensing of Environment, v. 205, p. 166–179, at https://doi.org/10.1016/j.rse.2017.11.019. |
Leveraging Google Earth Engine and semi-supervised generative adversarial networks to assess initial burn severity in forest | G. Wang, Y. Zhang, W. Xie, Y. Qu | 2022 | Wang, G., Zhang, Y., Xie, W., and Qu, Y., 2022, Leveraging Google Earth Engine and semi-supervised generative adversarial networks to assess initial burn severity in forest: Canadian Journal of Remote Sensing, v. 48, no. 3, p. 411–424, at https://doi.org/10.1080/07038992.2022.2054405. |
Impact of the 2016 southeastern US wildfires on the vertical distribution of ozone and aerosol at Huntsville, Alabama | B. Wang, S. Kuang, G. G. Pfister, A. Pour?Biazar, R. R. Buchholz, A. O. Langford, M. J. Newchurch | 2021 | Wang, B., Kuang, S., Pfister, G.G., Pour?Biazar, A., Buchholz, R.R., Langford, A.O., and Newchurch, M.J., 2021, Impact of the 2016 southeastern US wildfires on the vertical distribution of ozone and aerosol at Huntsville, Alabama: Journal of Geophysical Research—Atmospheres, v. 126, no. 9, article e2021JD034796, at https://doi.org/10.1029/2021jd034796. |
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Modeling wildfire effects on streamflow in the Cascade Mountains, Oregon, USA | K. A. Wampler, K. D. Bladon, M. Faramarzi | 2023 | Wampler, K.A., Bladon, K.D., and Faramarzi, M., 2023, Modeling wildfire effects on streamflow in the Cascade Mountains, Oregon, USA: Journal of Hydrology, v. 621, article 129585, at https://doi.org/10.1016/j.jhydrol.2023.129585. |
How local are the local economic impacts of wildfires? | Walls, M.A., Wibbenmeyer, M. | 2023 | Walls, M.A., and Wibbenmeyer, M., 2023, How local are the local economic impacts of wildfires?: Washington, D.C., Resources for the Future Working Paper 23-03, 38 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-23-03. |
Predicting post?fire debris flow grain sizes and depositional volumes in the Intermountain West, United States | S. Wall, B. P. Murphy, P. Belmont, L. Yocom | 2023 | Wall, S., Murphy, B.P., Belmont, P., and Yocom, L., 2023, Predicting post?fire debris flow grain sizes and depositional volumes in the Intermountain West, United States: Earth Surface Processes and Landforms, v. 48, no. 1, p. 179–197, at https://doi.org/10.1002/esp.5480. |
Fire regimes approaching historic norms reduce wildfire-facilitated conversion from forest to non-forest | R. B. Walker, J. D. Coop, S. A. Parks, L. Trader | 2018 | Walker, R.B., Coop, J.D., Parks, S.A., and Trader, L., 2018, Fire regimes approaching historic norms reduce wildfire-facilitated conversion from forest to non-forest: Ecosphere, v. 9, no. 4, article e02182, at https://doi.org/10.1002/ecs2.2182. |
How much forest persists through fire? High-resolution mapping of tree cover to characterize the abundance and spatial pattern of fire refugia across mosaics of burn severity | R. B. Walker, J. D. Coop, W. M. Downing, M. A. Krawchuk, S. L. Malone, G. W. Meigs | 2019 | Walker, R.B., Coop, J.D., Downing, W.M., Krawchuk, M.A., Malone, S.L., and Meigs, G.W., 2019, How much forest persists through fire? High-resolution mapping of tree cover to characterize the abundance and spatial pattern of fire refugia across mosaics of burn severity: Forests, v. 10, no. 9, article 782, at https://doi.org/10.3390/f10090782. |
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A large source of dust missing in particulate matter emission inventories? Wind erosion of post-fire landscapes | N. S. Wagenbrenner, S. H. Chung, B. K. Lamb, D. Helmig, G. Pfister | 2017 | Wagenbrenner, N.S., Chung, S.H., Lamb, B.K., Helmig, D., and Pfister, G., 2017, A large source of dust missing in particulate matter emission inventories? Wind erosion of post-fire landscapes: Elementa—Science of the Anthropocene, v. 5, article 2, at https://doi.org/10.1525/elementa.185. |
Observations and predictability of gap winds in the Salmon River Canyon of central Idaho, USA | N. Wagenbrenner, J. Forthofer, C. Gibson, A. Indreland, B. Lamb, B. Butler | 2018 | Wagenbrenner, N., Forthofer, J., Gibson, C., Indreland, A., Lamb, B., and Butler, B., 2018, Observations and predictability of gap winds in the Salmon River Canyon of central Idaho, USA: Atmosphere, v. 9, no. 2, article 45, at https://doi.org/10.3390/atmos9020045. |
Post-wildfire hydrologic recovery in Mediterranean climates—A systematic review and case study to identify current knowledge and opportunities | J. W. Wagenbrenner, B. A. Ebel, K. D. Bladon, A. M. Kinoshita | 2021 | Wagenbrenner, J.W., Ebel, B.A., Bladon, K.D., and Kinoshita, A.M., 2021, Post-wildfire hydrologic recovery in Mediterranean climates—A systematic review and case study to identify current knowledge and opportunities: Journal of Hydrology, v. 602, article 126772, at https://doi.org/10.1016/j.jhydrol.2021.126772. |
Housing density and ecosystem function—Comparing the impacts of rural, exurban, and suburban densities on fire hazard, water availability, and house and road distance effects | J. Vukomanovic, S. L. Doumas, W. R. Osterkamp, B. J. Orr | 2013 | Vukomanovic, J., Doumas, S.L., Osterkamp, W.R., and Orr, B.J., 2013, Housing density and ecosystem function—Comparing the impacts of rural, exurban, and suburban densities on fire hazard, water availability, and house and road distance effects: Land, v. 2, no. 4, p. 656–677, at https://doi.org/10.3390/land2040656. |
Effects of burn severity and postfire salvage logging on carnivore communities in montane forests | L. A. Volkmann, K. E. Hodges | 2024 | Volkmann, L.A., and Hodges, K.E., 2024, Effects of burn severity and postfire salvage logging on carnivore communities in montane forests: Journal of Mammalogy, v. 105, no. 2, p. 390–403, at https://doi.org/10.1093/jmammal/gyad135. |
Post-fire movements of Pacific marten (Martes caurina) depend on the severity of landscape change | L. A. Volkmann, K. E. Hodges | 2021 | Volkmann, L.A., and Hodges, K.E., 2021, Post-fire movements of Pacific marten (Martes caurina) depend on the severity of landscape change: Movement Ecology, v. 9, no. 1, article 49, at https://doi.org/10.1186/s40462-021-00286-2. |
Monitoring gradual ecosystem change using Landsat time series analyses—Case studies in selected forest and rangeland ecosystems | J. E. Vogelmann, G. Xian, C. Homer, B. Tolk | 2012 | Vogelmann, J.E., Xian, G., Homer, C., and Tolk, B., 2012, Monitoring gradual ecosystem change using Landsat time series analyses—Case studies in selected forest and rangeland ecosystems: Remote Sensing of Environment, v. 122, p. 92–105, at https://doi.org/10.1016/j.rse.2011.06.027. |
Monitoring landscape change for LANDFIRE using multi-temporal satellite imagery and ancillary data | J. E. Vogelmann, J. R. Kost, B. Tolk, S. Howard, K. Short, X. Chen, C. Huang, K. Pabst, M. G. Rollins | 2011 | Vogelmann, J.E., Kost, J.R., Tolk, B., Howard, S., Short, K., Chen, X., Huang, C., Pabst, K., and Rollins, M.G., 2011, Monitoring landscape change for LANDFIRE using multi-temporal satellite imagery and ancillary data: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, v. 4, no. 2, p. 252–264, at https://doi.org/10.1109/JSTARS.2010.2044478. |
Mapping post-fire habitat characteristics through the fusion of remote sensing tools | J. C. Vogeler, Z. Q. Yang, W. B. Cohen | 2016 | Vogeler, J.C., Yang, Z.Q., and Cohen, W.B., 2016, Mapping post-fire habitat characteristics through the fusion of remote sensing tools: Remote Sensing of Environment, v. 173, p. 294–303, at https://doi.org/10.1016/j.rse.2015.08.011. |
Mapping suitable Lewis's woodpecker nesting habitat in a post-fire landscape | J. C. Vogeler, Z. Yang, W. B. Cohen | 2016 | Vogeler, J.C., Yang, Z., and Cohen, W.B., 2016, Mapping suitable Lewis's woodpecker nesting habitat in a post-fire landscape: Northwest Science, v. 90, no. 4, p. 421–432, at https://doi.org/10.3955/046.090.0404. |
Characterizing over four decades of forest disturbance in Minnesota, USA | J. C. Vogeler, R. A. Slesak, P. A. Fekety, M. J. Falkowski | 2020 | Vogeler, J.C., Slesak, R.A., Fekety, P.A., and Falkowski, M.J., 2020, Characterizing over four decades of forest disturbance in Minnesota, USA: Forests, v. 11, no. 3, article 362, at https://doi.org/10.3390/f11030362. |
Landsat time series assessment of invasive annual grasses following energy development | M. L. Villarreal, C. E. Soulard, E. K. Waller | 2019 | Villarreal, M.L., Soulard, C.E., and Waller, E.K., 2019, Landsat time series assessment of invasive annual grasses following energy development: Remote Sensing, v. 11, no. 21, article 2553, at https://doi.org/10.3390/rs11212553. |
Contemporary fire regimes provide a critical perspective on restoration needs in the Mexico-United States borderlands | M. L. Villarreal, J. M. Iniguez, A. D. Flesch, J. S. Sanderlin, C. Cortés Montaño, C. R. Conrad, S. L. Haire | 2020 | Villarreal, M.L., Iniguez, J.M., Flesch, A.D., Sanderlin, J.S., Cortés Montaño, C., Conrad, C.R., and Haire, S.L., 2020, Contemporary fire regimes provide a critical perspective on restoration needs in the Mexico-United States borderlands: Air, Soil and Water Research, v. 13, p. 1–18, at https://doi.org/10.1177/1178622120969191. |
Distant neighbors—Recent wildfire patterns of the Madrean Sky Islands of southwestern United States and northwestern Mexico | M. L. Villarreal, S. L. Haire, J. M. Iniguez, C. C. Montano, T. B. Poitras | 2019 | Villarreal, M.L., Haire, S.L., Iniguez, J.M., Montano, C.C., and Poitras, T.B., 2019, Distant neighbors—Recent wildfire patterns of the Madrean Sky Islands of southwestern United States and northwestern Mexico: Fire Ecology, v. 15, no. 1, article 2, at https://doi.org/10.1186/s42408-018-0012-x. |
Characterizing ground and surface fuels across Sierra Nevada forests shortly after the 2012–2016 drought | E. Vilanova, L. A. Mortenson, L. E. Cox, B. M. Bulaon, J. M. Lydersen, C. J. Fettig, J. J. Battles, J. N. Axelson | 2023 | Vilanova, E., Mortenson, L.A., Cox, L.E., Bulaon, B.M., Lydersen, J.M., Fettig, C.J., Battles, J.J., and Axelson, J.N., 2023, Characterizing ground and surface fuels across Sierra Nevada forests shortly after the 2012–2016 drought: Forest Ecology and Management, v. 537, article 120945, at https://doi.org/10.1016/j.foreco.2023.120945. |
Daily burned area and carbon emissions from boreal fires in Alaska | S. Veraverbeke, B. M. Rogers, J. T. Randerson | 2015 | Veraverbeke, S., Rogers, B.M., and Randerson, J.T., 2015, Daily burned area and carbon emissions from boreal fires in Alaska: Biogeosciences, v. 12, no. 11, p. 3579–3601, at https://doi.org/10.5194/bg-12-3579-2015. |
Evaluating spectral indices and spectral mixture analysis for assessing fire severity, combustion completeness and carbon emissions | S. Veraverbeke, S. J. Hook | 2013 | Veraverbeke, S., and Hook, S.J., 2013, Evaluating spectral indices and spectral mixture analysis for assessing fire severity, combustion completeness and carbon emissions: International Journal of Wildland Fire, v. 22, no. 5, p. 707–720, at https://doi.org/10.1071/WF12168. |
Carbon credit possibilities and economic implications of fuel reduction treatments | T. Vegh, C.-H. Huang, A. Finkral | 2013 | Vegh, T., Huang, C.-H., and Finkral, A., 2013, Carbon credit possibilities and economic implications of fuel reduction treatments: Western Journal of Applied Forestry, v. 28, no. 2, p. 57–65, at https://doi.org/10.5849/wjaf.12-006. |
Modeling the influence of climate and local site factors on post-fire regeneration in the Southern Rocky Mountains, Final Report | Veblen, T., Rodman, K. | 2019 | Veblen, T., and Rodman, K., 2019, Modeling the influence of climate and local site factors on post-fire regeneration in the Southern Rocky Mountains, Final Report: Joint Fire Science Program JFSP PROJECT ID—17-2-01-4, 32 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JK%3FV%20%20%20%0A. |
Environmental change, shifting distributions, and habitat conservation plans—A case study of the California gnatcatcher | H. L. Hulton VanTassel, M. D. Bell, J. Rotenberry, R. Johnson, M. F. Allen | 2017 | Hulton VanTassel, H.L., Bell, M.D., Rotenberry, J., Johnson, R., and Allen, M.F., 2017, Environmental change, shifting distributions, and habitat conservation plans—A case study of the California gnatcatcher: Ecology and Evolution, v. 7, no. 23, p. 10326–10338, at https://doi.org/10.1002/ece3.3482. |
Persistence of MODIS evapotranspiration impacts from mountain pine beetle outbreaks in lodgepole pine forests, south-central Rocky Mountains | M. K. Vanderhoof, C. A. Williams | 2015 | Vanderhoof, M.K., and Williams, C.A., 2015, Persistence of MODIS evapotranspiration impacts from mountain pine beetle outbreaks in lodgepole pine forests, south-central Rocky Mountains: Agricultural and Forest Meteorology, v. 200, p. 78–91, at https://doi.org/10.1016/j.agrformet.2014.09.015. |
Contemporary (1984–2020) fire history metrics for the conterminous United States and ecoregional differences by land ownership | M. K. Vanderhoof, T. J. Hawbaker, C. Teske, J. Noble, J. Smith | 2022 | Vanderhoof, M.K., Hawbaker, T.J., Teske, C., Noble, J., and Smith, J., 2022, Contemporary (1984–2020) fire history metrics for the conterminous United States and ecoregional differences by land ownership: International Journal of Wildland Fire, v. 31, no. 12, p. 1167–1183, at https://doi.org/10.1071/WF22044. |
Mapping wetland burned area from Sentinel-2 across the southeastern United States and its contributions relative to Landsat-8 (2016–2019) | M. K. Vanderhoof, T. J. Hawbaker, C. Teske, A. Ku, J. Noble, J. Picotte | 2021 | Vanderhoof, M.K., Hawbaker, T.J., Teske, C., Ku, A., Noble, J., and Picotte, J., 2021, Mapping wetland burned area from Sentinel-2 across the southeastern United States and its contributions relative to Landsat-8 (2016–2019): Fire, v. 4, no. 3, article 52, at https://doi.org/10.3390/fire4030052. |
Validation of the USGS Landsat Burned Area Essential Climate Variable (BAECV) across the conterminous United States | M. K. Vanderhoof, N. Fairaux, Y.-J. G. Beal, T. J. Hawbaker | 2017 | Vanderhoof, M.K., Fairaux, N., Beal, Y.-J.G., and Hawbaker, T.J., 2017, Validation of the USGS Landsat Burned Area Essential Climate Variable (BAECV) across the conterminous United States: Remote Sensing of Environment, v. 198, p. 393–406, at https://doi.org/10.1016/j.rse.2017.06.025. |
Time series of high-resolution images enhances efforts to monitor post-fire condition and recovery, Waldo Canyon fire, Colorado, USA | M. K. Vanderhoof, C. Burt, T. J. Hawbaker | 2018 | Vanderhoof, M.K., Burt, C., and Hawbaker, T.J., 2018, Time series of high-resolution images enhances efforts to monitor post-fire condition and recovery, Waldo Canyon fire, Colorado, USA: International Journal of Wildland Fire, v. 27, no. 10, p. 699–713, at https://doi.org/10.1071/Wf17177. |
Albedo-induced radiative forcing from mountain pine beetle outbreaks in forests, south-central Rocky Mountains—Magnitude, persistence, and relation to outbreak severity | M. Vanderhoof, C. A. Williams, Y. Shuai, D. Jarvis, D. Kulakowski, J. Masek | 2014 | Vanderhoof, M., Williams, C.A., Shuai, Y., Jarvis, D., Kulakowski, D., and Masek, J., 2014, Albedo-induced radiative forcing from mountain pine beetle outbreaks in forests, south-central Rocky Mountains—Magnitude, persistence, and relation to outbreak severity: Biogeosciences, v. 11, no. 3, p. 563–575, at https://doi.org/10.5194/bg-11-563-2014. |
Impact of mountain pine beetle outbreaks on forest albedo and radiative forcing, as derived from Moderate Resolution Imaging Spectroradiometer, Rocky Mountains, USA | M. Vanderhoof, C. A. Williams, B. Ghimire, J. Rogan | 2013 | Vanderhoof, M., Williams, C.A., Ghimire, B., and Rogan, J., 2013, Impact of mountain pine beetle outbreaks on forest albedo and radiative forcing, as derived from Moderate Resolution Imaging Spectroradiometer, Rocky Mountains, USA: Journal of Geophysical Research—Biogeosciences, v. 118, no. 4, p. 1461–1471, at https://doi.org/10.1002/jgrg.20120. |
Evaluation of the U.S. Geological Survey Landsat Burned Area Essential Climate Variable across the conterminous U.S. using commercial high-resolution imagery | K. M. Vanderhoof, N. Brunner, G. Y.-J. Beal, J. T. Hawbaker | 2017 | Vanderhoof, K.M., Brunner, N., Beal, G.Y.-J., and Hawbaker, J.T., 2017, Evaluation of the U.S. Geological Survey Landsat Burned Area Essential Climate Variable across the conterminous U.S. using commercial high-resolution imagery: Remote Sensing, v. 9, no. 7, article 743, at https://doi.org/10.3390/rs9070743. |
An evaluation of the forest service hazardous fuels treatment program—Are we treating enough to promote resiliency or reduce hazard? | N. M. Vaillant, E. D. Reinhardt | 2017 | Vaillant, N.M., and Reinhardt, E.D., 2017, An evaluation of the forest service hazardous fuels treatment program—Are we treating enough to promote resiliency or reduce hazard?: Journal of Forestry, v. 115, no. 4, p. 300–308, at https://doi.org/10.5849/jof.16-067. |
Assessing landscape vulnerability to wildfire in the USA | N. M. Vaillant, C. A. Kolden, A. M. S. Smith | 2016 | Vaillant, N.M., Kolden, C.A., and Smith, A.M.S., 2016, Assessing landscape vulnerability to wildfire in the USA: Current Forestry Reports, v. 2, no. 3, p. 201–213, at https://doi.org/10.1007/s40725-016-0040-1. |
Developing an online tool for identifying at-risk populations to wildfire smoke hazards | A. Vaidyanathan, F. Yip, P. Garbe | 2018 | Vaidyanathan, A., Yip, F., and Garbe, P., 2018, Developing an online tool for identifying at-risk populations to wildfire smoke hazards: Science of the Total Environment, v. 619–620, p. 376–383, at https://doi.org/10.1016/j.scitotenv.2017.10.270. |
Evidence of widespread topoclimatic limitation for lower treelines of the Intermountain West, United States | A. K. Urza, P. J. Weisberg, T. Dilts | 2020 | Urza, A.K., Weisberg, P.J., and Dilts, T., 2020, Evidence of widespread topoclimatic limitation for lower treelines of the Intermountain West, United States: Ecological Applications, v. 30, no. 7, article e02158, at https://doi.org/10.1002/eap.2158. |
Contiguous United States wildland fire emission estimates during 2003–2015 | S. P. Urbanski, M. C. Reeves, R. E. Corley, R. P. Silverstein, W. M. Hao | 2018 | Urbanski, S.P., Reeves, M.C., Corley, R.E., Silverstein, R.P., and Hao, W.M., 2018, Contiguous United States wildland fire emission estimates during 2003–2015: Earth System Science Data, v. 10, no. 4, p. 2241–2274, at https://doi.org/10.5194/essd-10-2241-2018. |
The Wildland Fire Emission Inventory—Western United States emission estimates and an evaluation of uncertainty | S. P. Urbanski, W. M. Hao, B. Nordgren | 2011 | Urbanski, S.P., Hao, W.M., and Nordgren, B., 2011, The Wildland Fire Emission Inventory—Western United States emission estimates and an evaluation of uncertainty: Atmospheric Chemistry and Physics, v. 11, no. 24, p. 12973–13000, at https://doi.org/10.5194/acp-11-12973-2011. |
Combustion efficiency and emission factors for wildfire-season fires in mixed conifer forests of the Northern Rocky Mountains, US | S. P. Urbanski | 2013 | Urbanski, S.P., 2013, Combustion efficiency and emission factors for wildfire-season fires in mixed conifer forests of the Northern Rocky Mountains, US: Atmospheric Chemistry and Physics, v. 13, no. 14, p. 7241–7262, at https://doi.org/10.5194/acp-13-7241-2013. |
A VIIRS direct broadcast algorithm for rapid response mapping of wildfire burned area in the western United States | S. Urbanski, B. Nordgren, C. Albury, B. Schwert, D. Peterson, B. Quayle, W. M. Hao | 2018 | Urbanski, S., Nordgren, B., Albury, C., Schwert, B., Peterson, D., Quayle, B., and Hao, W.M., 2018, A VIIRS direct broadcast algorithm for rapid response mapping of wildfire burned area in the western United States: Remote Sensing of Environment, v. 219, p. 271–283, at https://doi.org/10.1016/j.rse.2018.10.007. |
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The post-wildfire impact of burn severity and age on black carbon snow deposition and implications for snow water resources, Cascade Range, Washington | T. M. Uecker, S. D. Kaspari, K. N. Musselman, S. McKenzie Skiles | 2020 | Uecker, T.M., Kaspari, S.D., Musselman, K.N., and McKenzie Skiles, S., 2020, The post-wildfire impact of burn severity and age on black carbon snow deposition and implications for snow water resources, Cascade Range, Washington: Journal of Hydrometeorology, v. 21, no. 8, p. 1777–1792, at https://doi.org/10.1175/JHM-D-20-0010.1. |
Wildfire immediately reduces nest and adult survival of greater sage-grouse | E. A. Tyrrell, P. S. Coates, B. G. Prochazka, B. E. Brussee, S. P. Espinosa, J. M. Hull | 2023 | Tyrrell, E.A., Coates, P.S., Prochazka, B.G., Brussee, B.E., Espinosa, S.P., and Hull, J.M., 2023, Wildfire immediately reduces nest and adult survival of greater sage-grouse: Scientific Reports, v. 13, no. 1, article 10970, at https://doi.org/10.1038/s41598-023-32937-2. |
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Twenty-four years after the Yellowstone Fires—Are postfire lodgepole pine stands converging in structure and function? | M. G. Turner, T. G. Whitby, D. B. Tinker, W. H. Romme | 2016 | Turner, M.G., Whitby, T.G., Tinker, D.B., and Romme, W.H., 2016, Twenty-four years after the Yellowstone Fires—Are postfire lodgepole pine stands converging in structure and function?: Ecology, v. 97, no. 5, p. 1260–73, at https://doi.org/10.1890/15-1585.1. |
The magnitude, direction, and tempo of forest change in Greater Yellowstone in a warmer world with more fire | M. G. Turner, K. H. Braziunas, W. D. Hansen, T. J. Hoecker, W. Rammer, Z. Ratajczak, A. L. Westerling, R. Seidl | 2022 | Turner, M.G., Braziunas, K.H., Hansen, W.D., Hoecker, T.J., Rammer, W., Ratajczak, Z., Westerling, A.L., and Seidl, R., 2022, The magnitude, direction, and tempo of forest change in Greater Yellowstone in a warmer world with more fire: Ecological Monographs, v. 92, no. 1, article e1485, at https://doi.org/10.1002/ecm.1485. |
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Anthropogenic climate change impacts exacerbate summer forest fires in California | M. Turco, J. T. Abatzoglou, S. Herrera, Y. Zhuang, S. Jerez, D. D. Lucas, A. AghaKouchak, I. Cvijanovic | 2023 | Turco, M., Abatzoglou, J.T., Herrera, S., Zhuang, Y., Jerez, S., Lucas, D.D., AghaKouchak, A., and Cvijanovic, I., 2023, Anthropogenic climate change impacts exacerbate summer forest fires in California: Proceedings of the National Academy of Sciences of the United States of America, v. 120, no. 25, article e2213815120, at https://doi.org/10.1073/pnas.2213815120. |
Groundwater from perennial springs provide refuge from wildfire impacts in mountainous semiarid watershed | L. M. Tsinnajinnie, M. D. Frisbee, J. L. Wilson | 2021 | Tsinnajinnie, L.M., Frisbee, M.D., and Wilson, J.L., 2021, Groundwater from perennial springs provide refuge from wildfire impacts in mountainous semiarid watershed: Journal of Hydrology, v. 596, article 125701, at https://doi.org/10.1016/j.jhydrol.2020.125701. |
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Vegetation-Rainfall interactions reveal how climate variability and climate change alter spatial patterns of wildland fire probability on Big Island, Hawaii | C. Trauernicht | 2018 | Trauernicht, C., 2018, Vegetation-Rainfall interactions reveal how climate variability and climate change alter spatial patterns of wildland fire probability on Big Island, Hawaii: Science of the Total Environment, v. 650, pt. 1, p. 459–469, at https://doi.org/10.1016/j.scitotenv.2018.08.347. |
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Potential postwildfire debris-flow hazards—A prewildfire evaluation for the Jemez Mountains, north-central New Mexico | Tillery, Anne C., Haas, Jessica R. | 2016 | Tillery, A.C., and Haas, J.R., 2016, Potential postwildfire debris-flow hazards—A prewildfire evaluation for the Jemez Mountains, north-central New Mexico: Reston, Va., U.S. Geological Survey Scientific-Investigations Report 2016-5101, 27 p., at https://doi.org/10.3133/sir20165101. |
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Integrated wildfire risk assessment—Framework development and application on the Lewis and Clark National Forest in Montana, USA | M. P. Thompson, J. Scott, D. Helmbrecht, D. E. Calkin | 2013 | Thompson, M.P., Scott, J., Helmbrecht, D., and Calkin, D.E., 2013, Integrated wildfire risk assessment—Framework development and application on the Lewis and Clark National Forest in Montana, USA: Integrated Environmental Assessment and Management, v. 9, no. 2, p. 329–342, at https://doi.org/10.1002/ieam.1365. |
Forest roads and operational wildfire response planning | M. P. Thompson, B. M. Gannon, M. D. Caggiano | 2021 | Thompson, M.P., Gannon, B.M., and Caggiano, M.D., 2021, Forest roads and operational wildfire response planning: Forests, v. 12, no. 2, article 110, at https://doi.org/10.3390/f12020110. |
Quantifying the influence of previously burned areas on suppression effectiveness and avoided exposure—A case study of the Las Conchas Fire | M. P. Thompson, P. Freeborn, J. D. Rieck, D. E. Calkin, J. W. Gilbertson-Day, M. A. Cochrane, M. S. Hand | 2016 | Thompson, M.P., Freeborn, P., Rieck, J.D., Calkin, D.E., Gilbertson-Day, J.W., Cochrane, M.A., and Hand, M.S., 2016, Quantifying the influence of previously burned areas on suppression effectiveness and avoided exposure—A case study of the Las Conchas Fire: International Journal of Wildland Fire, v. 25, no. 2, p. 167–181, at https://doi.org/10.1071/WF14216. |
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Validation of North American Forest Disturbance dynamics derived from Landsat time series stacks | N. E. Thomas, C. Huang, S. N. Goward, S. Powell, K. Rishmawi, K. Schleeweis, A. Hinds | 2011 | Thomas, N.E., Huang, C., Goward, S.N., Powell, S., Rishmawi, K., Schleeweis, K., and Hinds, A., 2011, Validation of North American Forest Disturbance dynamics derived from Landsat time series stacks: Remote Sensing of Environment, v. 115, no. 1, p. 19–32, at https://doi.org/10.1016/j.rse.2010.07.009. |
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Modeling acute respiratory illness during the 2007 San Diego wildland fires using a coupled emissions-transport system and generalized additive modeling | B. Thelen, N. H. French, B. W. Koziol, M. Billmire, R. C. Owen, J. Johnson, M. Ginsberg, T. Loboda, S. Wu | 2013 | Thelen, B., French, N.H., Koziol, B.W., Billmire, M., Owen, R.C., Johnson, J., Ginsberg, M., Loboda, T., and Wu, S., 2013, Modeling acute respiratory illness during the 2007 San Diego wildland fires using a coupled emissions-transport system and generalized additive modeling: Environmental Health, v. 12, article 94, at https://doi.org/10.1186/1476-069X-12-94. |
Characterizing fire-on-fire interactions in three large wilderness areas | C. C. Teske, C. A. Seielstad, L. P. Queen | 2012 | Teske, C.C., Seielstad, C.A., and Queen, L.P., 2012, Characterizing fire-on-fire interactions in three large wilderness areas: Fire Ecology, v. 8, no. 2, p. 82–106, at https://doi.org/10.4996/fireecology.0802082. |
Population decline in California spotted owls near their southern range boundary | D. J. Tempel, H. A. Kramer, G. M. Jones, R. J. Gutiérrez, S. C. Sawyer, A. Koltunov, M. Slaton, R. Tanner, B. K. Hobart, M. Z. Peery | 2022 | Tempel, D.J., Kramer, H.A., Jones, G.M., Gutiérrez, R.J., Sawyer, S.C., Koltunov, A., Slaton, M., Tanner, R., Hobart, B.K., and Peery, M.Z., 2022, Population decline in California spotted owls near their southern range boundary: The Journal of Wildlife Management, v. 86, no. 2, article e22168, at https://doi.org/10.1002/jwmg.22168. |
Evaluating short- and long-term impacts of fuels treatments and simulated wildfire on an old-forest species | D. J. Tempel, R. J. Gutiérrez, J. J. Battles, D. L. Fry, Y. Su, Q. Guo, M. J. Reetz, S. A. Whitmore, G. M. Jones, B. M. Collins, S. L. Stephens, M. Kelly, W. J. Berigan, M. Z. Peery | 2015 | Tempel, D.J., Gutiérrez, R.J., Battles, J.J., Fry, D.L., Su, Y., Guo, Q., Reetz, M.J., Whitmore, S.A., Jones, G.M., et al., 2015, Evaluating short- and long-term impacts of fuels treatments and simulated wildfire on an old-forest species: Ecosphere, v. 6, no. 12, article 261, at https://doi.org/10.1890/ES15-00234.1. |
Sensitivity to spatial and temporal scale and fire regime inputs in deriving fire regime condition class | Tedrow, L., Hann, W.J. | 2015 | Tedrow, L., and Hann, W.J., 2015, Sensitivity to spatial and temporal scale and fire regime inputs in deriving fire regime condition class, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 237–246, at https://www.fs.usda.gov/research/treesearch/49449. |
The economics of ecological restoration and hazardous fuel reduction treatments in the ponderosa pine forest ecosystem | M. H. Taylor, A. J. S. Meador, Y. S. Kim, K. Rollins, H. Will | 2015 | Taylor, M.H., Meador, A.J.S., Kim, Y.S., Rollins, K., and Will, H., 2015, The economics of ecological restoration and hazardous fuel reduction treatments in the ponderosa pine forest ecosystem: Forest Science, v. 61, no. 6, p. 988–1008, at https://doi.org/10.5849/forsci.14-030. |
Controls on spatial patterns of wildfire severity and early post-fire vegetation development in an Arizona Sky Island, USA | A. H. Taylor, H. M. Poulos, J. Kluber, R. Issacs, N. Pawlikowski, A. M. Barton | 2021 | Taylor, A.H., Poulos, H.M., Kluber, J., Issacs, R., Pawlikowski, N., and Barton, A.M., 2021, Controls on spatial patterns of wildfire severity and early post-fire vegetation development in an Arizona Sky Island, USA: Landscape Ecology, v. 36, p. 2637–2656, at https://doi.org/10.1007/s10980-021-01260-4. |
Drivers of fire severity shift as landscapes transition to an active fire regime, Klamath Mountains, USA | A. H. Taylor, L. B. Harris, S. A. Drury | 2021 | Taylor, A.H., Harris, L.B., and Drury, S.A., 2021, Drivers of fire severity shift as landscapes transition to an active fire regime, Klamath Mountains, USA: Ecosphere, v. 12, no. 9, article e03734, at https://doi.org/10.1002/ecs2.3734. |
Spatial patterns of nineteenth century fire severity persist after fire exclusion and a twenty-first century wildfire in a mixed conifer forest landscape, southern Cascades, USA | A. H. Taylor, C. Airey-Lauvaux, B. Estes, L. Harris, C. N. Skinner | 2020 | Taylor, A.H., Airey-Lauvaux, C., Estes, B., Harris, L., and Skinner, C.N., 2020, Spatial patterns of nineteenth century fire severity persist after fire exclusion and a twenty-first century wildfire in a mixed conifer forest landscape, southern Cascades, USA: Landscape Ecology, v. 35, no. 12, p. 2777–2790, at https://doi.org/10.1007/s10980-020-01118-1. |
Radar Burn Ratio for fire severity estimation at canopy level—An example for temperate forests | M. A. Tanase, R. Kennedy, C. Aponte | 2015 | Tanase, M.A., Kennedy, R., and Aponte, C., 2015, Radar Burn Ratio for fire severity estimation at canopy level—An example for temperate forests: Remote Sensing of Environment, v. 170, p. 14–31, at https://doi.org/10.1016/j.rse.2015.08.025. |
MODIS-informed greenness responses to daytime land surface temperature fluctuations and wildfire disturbances in the Alaskan Yukon River Basin | Z. Tan, S. Liu, B. K. Wylie, C. B. Jenkerson, J. Oeding, J. Rover, C. Young | 2013 | Tan, Z., Liu, S., Wylie, B.K., Jenkerson, C.B., Oeding, J., Rover, J., and Young, C., 2013, MODIS-informed greenness responses to daytime land surface temperature fluctuations and wildfire disturbances in the Alaskan Yukon River Basin: International Journal of Remote Sensing, v. 34, no. 6, p. 2187–2199, at https://doi.org/10.1080/01431161.2012.742215. |
An added boost in pyrogenic carbon when wildfire burns forest with high pre-fire mortality | A. C. Talucci, L. M. Matosziuk, J. A. Hatten, M. A. Krawchuk | 2020 | Talucci, A.C., Matosziuk, L.M., Hatten, J.A., and Krawchuk, M.A., 2020, An added boost in pyrogenic carbon when wildfire burns forest with high pre-fire mortality: Fire Ecology, v. 16, no. 1, article 21, at https://doi.org/10.1186/s42408-020-00081-1. |
Spatial patterns of unburned refugia in Siberian larch forests during the exceptional 2020 fire season | A. C. Talucci, M. M. Loranty, H. D. Alexander | 2022 | Talucci, A.C., Loranty, M.M., and Alexander, H.D., 2022, Spatial patterns of unburned refugia in Siberian larch forests during the exceptional 2020 fire season: Global Ecology and Biogeography, v. 31, no. 10, p. 2041–2055, at https://doi.org/10.1111/geb.13529. |
Siberian taiga and tundra fire regimes from 2001–2020 | A. C. Talucci, M. M. Loranty, H. D. Alexander | 2022 | Talucci, A.C., Loranty, M.M., and Alexander, H.D., 2022, Siberian taiga and tundra fire regimes from 2001–2020: Environmental Research Letters, v. 17, no. 2, article 025001, at https://doi.org/10.1088/1748-9326/ac3f07. |
Drivers of lodgepole pine recruitment across a gradient of bark beetle outbreak and wildfire in British Columbia | A. C. Talucci, K. P. Lertzman, M. A. Krawchuk | 2019 | Talucci, A.C., Lertzman, K.P., and Krawchuk, M.A., 2019, Drivers of lodgepole pine recruitment across a gradient of bark beetle outbreak and wildfire in British Columbia: Forest Ecology and Management, v. 451, article 117500, at https://doi.org/10.1016/j.foreco.2019.117500. |
Dead forests burning—The influence of beetle outbreaks on fire severity and legacy structure in sub-boreal forests | A. C. Talucci, M. A. Krawchuk | 2019 | Talucci, A.C., and Krawchuk, M.A., 2019, Dead forests burning—The influence of beetle outbreaks on fire severity and legacy structure in sub-boreal forests: Ecosphere, v. 10, no. 5, article e02744, at https://doi.org/10.1002/ecs2.2744. |
Bird community shifts associated with saltwater exposure in coastal forests at the leading edge of rising sea level | P. J. Taillie, C. E. Moorman, L. S. Smart, K. Pacifici | 2019 | Taillie, P.J., Moorman, C.E., Smart, L.S., and Pacifici, K., 2019, Bird community shifts associated with saltwater exposure in coastal forests at the leading edge of rising sea level: PLoS ONE, v. 14, no. 5, article e0216540, at https://doi.org/10.1371/journal.pone.0216540. |
Marsh bird occupancy along the shoreline-to-forest gradient as marshes migrate from rising sea level | P. J. Taillie, C. E. Moorman | 2019 | Taillie, P.J., and Moorman, C.E., 2019, Marsh bird occupancy along the shoreline-to-forest gradient as marshes migrate from rising sea level: Ecosphere, v. 10, no. 1, article e02555, at https://doi.org/10.1002/ecs2.2555. |
Interacting and non-linear avian responses to mixed-severity wildfire and time since fire | P. J. Taillie, R. D. Burnett, L. J. Roberts, B. R. Campos, M. N. Peterson, C. E. Moorman | 2018 | Taillie, P.J., Burnett, R.D., Roberts, L.J., Campos, B.R., Peterson, M.N., and Moorman, C.E., 2018, Interacting and non-linear avian responses to mixed-severity wildfire and time since fire: Ecosphere, v. 9, no. 6, article e02291, at https://doi.org/10.1002/ecs2.2291. |
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Regional context for balancing sagebrush- and woodland-dependent songbird needs with targeted pinyon-juniper management | J. D. Tack, J. T. Smith, K. E. Doherty, P. J. Donnelly, J. D. Maestas, B. W. Allred, J. Reinhardt, S. L. Morford, D. E. Naugle | 2023 | Tack, J.D., Smith, J.T., Doherty, K.E., Donnelly, P.J., Maestas, J.D., Allred, B.W., Reinhardt, J., Morford, S.L., and Naugle, D.E., 2023, Regional context for balancing sagebrush- and woodland-dependent songbird needs with targeted pinyon-juniper management: Rangeland Ecology & Management, v. 88, p. 182–191, at https://doi.org/10.1016/j.rama.2023.03.006. |
Assessing the use of burn ratios and red-edge spectral indices for detecting fire effects in the Greater Yellowstone Ecosystem | D. M. Szpakowski, J. L. R. Jensen, T. E. Chow, D. R. Butler | 2023 | Szpakowski, D.M., Jensen, J.L.R., Chow, T.E., and Butler, D.R., 2023, Assessing the use of burn ratios and red-edge spectral indices for detecting fire effects in the Greater Yellowstone Ecosystem: Forests, v. 14, no. 7, article 1508, at https://doi.org/10.3390/f14071508. |
A study of the relationship between fire hazard and burn severity in Grand Teton National Park, USA | D. M. Szpakowski, J. L. R. Jensen, D. R. Butler, T. E. Chow | 2021 | Szpakowski, D.M., Jensen, J.L.R., Butler, D.R., and Chow, T.E., 2021, A study of the relationship between fire hazard and burn severity in Grand Teton National Park, USA: International Journal of Applied Earth Observation and Geoinformation, v. 98, article 102305, at https://doi.org/10.1016/j.jag.2021.102305. |
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Quantifying drought-induced tree mortality in the open canopy woodlands of central Texas | A. M. Schwantes, J. J. Swenson, R. B. Jackson | 2016 | Schwantes, A.M., Swenson, J.J., and Jackson, R.B., 2016, Quantifying drought-induced tree mortality in the open canopy woodlands of central Texas: Remote Sensing of Environment, v. 181, p. 54–64, at https://doi.org/10.1016/j.rse.2016.03.027. |
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Temporal mismatch in space use by a sagebrush obligate species after large?scale wildfire | E. M. Schuyler, C. A. Hagen, C. R. Anthony, L. J. Foster, K. M. Dugger | 2022 | Schuyler, E.M., Hagen, C.A., Anthony, C.R., Foster, L.J., and Dugger, K.M., 2022, Temporal mismatch in space use by a sagebrush obligate species after large?scale wildfire: Ecosphere, v. 13, no. 9, article e4179, at https://doi.org/10.1002/ecs2.4179. |
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Automated burned area identification in real-time during wildfire events using WorldView imagery for the insurance industry | Schulz, Karsten, Michel, Ulrich, Geller, Christina | 2018 | Schulz, K., Michel, U., and Geller, C., 2018, Automated burned area identification in real-time during wildfire events using WorldView imagery for the insurance industry, in Earth Resources and Environmental Remote Sensing/GIS Applications IX, Berlin, Germany, 10-13 September 2018, Proc. of SPIE Vol. 10790: Bellingham, Wash., Society of Photo-Optical Instrumentation Engineers, paper 1079015, at https://doi.org/10.1117/12.2324458. |
Testing a Landsat-based approach for mapping disturbance causality in U.S. forests | T. A. Schroeder, K. G. Schleeweis, G. G. Moisen, C. Toney, W. B. Cohen, E. A. Freeman, Z. Yang, C. Huang | 2017 | Schroeder, T.A., Schleeweis, K.G., Moisen, G.G., Toney, C., Cohen, W.B., Freeman, E.A., Yang, Z., and Huang, C., 2017, Testing a Landsat-based approach for mapping disturbance causality in U.S. forests: Remote Sensing of Environment, v. 195, p. 230–243, at https://doi.org/10.1016/j.rse.2017.03.033. |
Improving estimates of forest disturbance by combining observations from Landsat time series with U.S. Forest Service Forest Inventory and Analysis data | T. A. Schroeder, S. P. Healey, G. G. Moisen, T. S. Frescino, W. B. Cohen, C. Huang, R. E. Kennedy, Z. Yang | 2014 | Schroeder, T.A., Healey, S.P., Moisen, G.G., Frescino, T.S., Cohen, W.B., Huang, C., Kennedy, R.E., and Yang, Z., 2014, Improving estimates of forest disturbance by combining observations from Landsat time series with U.S. Forest Service Forest Inventory and Analysis data: Remote Sensing of Environment, v. 154, no. 1, p. 61–73, at https://doi.org/10.1016/j.rse.2014.08.005. |
Soil seed bank composition and spatial distribution in a cheatgrass (Bromus tectorum L.)–dominated rangeland in Colorado, USA | R. W. R. Schroeder, J. L. Jonas, M. N. Grant-Hoffman, M. W. Paschke | 2023 | Schroeder, R.W.R., Jonas, J.L., Grant-Hoffman, M.N., and Paschke, M.W., 2023, Soil seed bank composition and spatial distribution in a cheatgrass (Bromus tectorum L.)–dominated rangeland in Colorado, USA: Western North American Naturalist, v. 83, no. 2, p. 191–206, at https://doi.org/10.3398/064.083.0205. |
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Grassland fragmentation and its influence on woody plant cover in the southern Great Plains, USA | R. Scholtz, J. A. Polo, E. P. Tanner, S. D. Fuhlendorf | 2018 | Scholtz, R., Polo, J.A., Tanner, E.P., and Fuhlendorf, S.D., 2018, Grassland fragmentation and its influence on woody plant cover in the southern Great Plains, USA: Landscape Ecology, v. 33, no. 10, p. 1785–1797, at https://doi.org/10.1007/s10980-018-0702-4. |
Climate-fire interactions constrain potential woody plant cover and stature in North American Great Plains grasslands | R. Scholtz, S. D. Fuhlendorf, S. R. Archer | 2018 | Scholtz, R., Fuhlendorf, S.D., and Archer, S.R., 2018, Climate-fire interactions constrain potential woody plant cover and stature in North American Great Plains grasslands: Global Ecology and Biogeography, v. 27, no. 8, p. 936–945, at https://doi.org/10.1111/geb.12752. |
Development of a source-specific biomass burning emissions inventory for Washington, Oregon, and California | C. L. Schollaert, M. E. Marlier, T. M. Busch Isaksen | 2024 | Schollaert, C.L., Marlier, M.E., and Busch Isaksen, T.M., 2024, Development of a source-specific biomass burning emissions inventory for Washington, Oregon, and California: Atmospheric Environment, v. 319, article 120283, at https://doi.org/10.1016/j.atmosenv.2023.120283. |
Adapt to more wildfire in western North American forests as climate changes | T. Schoennagel, J. K. Balch, H. Brenkert-Smith, P. E. Dennison, B. J. Harvey, M. A. Krawchuk, N. Mietkiewicz, P. Morgan, M. A. Moritz, R. Rasker, M. G. Turner, C. Whitlock | 2017 | Schoennagel, T., Balch, J.K., Brenkert-Smith, H., Dennison, P.E., Harvey, B.J., Krawchuk, M.A., Mietkiewicz, N., Morgan, P., Moritz, M.A., et al., 2017, Adapt to more wildfire in western North American forests as climate changes: Proceedings of the National Academy of Sciences of the United States of America, v. 114, no. 18, p. 4582–4590, at https://doi.org/10.1073/pnas.1617464114. |
A quantitative wildfire risk assessment using a modular approach of geostatistical clustering and regionally distinct valuations of assets—A case study in Oregon | A. Schmidt, D. Leavell, J. Punches, M. A. Rocha Ibarra, J. S. Kagan, M. Creutzburg, M. McCune, J. Salwasser, C. Walter, C. Berger | 2022 | Schmidt, A., Leavell, D., Punches, J., Rocha Ibarra, M.A., Kagan, J.S., Creutzburg, M., McCune, M., Salwasser, J., Walter, C., and Berger, C., 2022, A quantitative wildfire risk assessment using a modular approach of geostatistical clustering and regionally distinct valuations of assets—A case study in Oregon: PLoS ONE, v. 17, no. 3, article e0264826, at https://doi.org/10.1371/journal.pone.0264826. |
Bayesian optimization of the community land model simulated biosphere–atmosphere exchange using CO2 observations from a dense tower network and aircraft campaigns over Oregon | A. Schmidt, B. E. Law, M. Göckede, C. Hanson, Z. Yang, S. Conley | 2016 | Schmidt, A., Law, B.E., Göckede, M., Hanson, C., Yang, Z., and Conley, S., 2016, Bayesian optimization of the community land model simulated biosphere–atmosphere exchange using CO2 observations from a dense tower network and aircraft campaigns over Oregon: Earth Interactions, v. 20, no. 22, article 22, at https://doi.org/10.1175/ei-d-16-0011.1. |
Application of deep convolutional networks for improved risk assessments of post-wildfire drinking water contamination | A. Schmidt, L. M. Ellsworth, J. H. Tilt, M. Gough | 2023 | Schmidt, A., Ellsworth, L.M., Tilt, J.H., and Gough, M., 2023, Application of deep convolutional networks for improved risk assessments of post-wildfire drinking water contamination: Machine Learning with Applications, v. 11, article 100454, at https://doi.org/10.1016/j.mlwa.2023.100454. |
Predicting conditional maximum contaminant level exceedance probabilities for drinking water after wildfires with Bayesian regularized network ensembles | A. Schmidt, L. M. Ellsworth, J. H. Tilt, M. Gough | 2022 | Schmidt, A., Ellsworth, L.M., Tilt, J.H., and Gough, M., 2022, Predicting conditional maximum contaminant level exceedance probabilities for drinking water after wildfires with Bayesian regularized network ensembles: Machine Learning with Applications, v. 7, article 100227, at https://doi.org/10.1016/j.mlwa.2021.100227. |
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Regional dynamics of forest canopy change and underlying causal processes in the contiguous U.S. | K. Schleeweis, S. N. Goward, C. Huang, J. G. Masek, G. Moisen, R. E. Kennedy, N. E. Thomas | 2013 | Schleeweis, K., Goward, S.N., Huang, C., Masek, J.G., Moisen, G., Kennedy, R.E., and Thomas, N.E., 2013, Regional dynamics of forest canopy change and underlying causal processes in the contiguous U.S.: Journal of Geophysical Research—Biogeosciences, v. 118, no. 3, p. 1035–1053, at https://doi.org/10.1002/jgrg.20076. |
Improved burn severity estimation by using land surface phenology metrics and red edge information estimated from Landsat | D. Scheffler, D. Frantz | 2022 | Scheffler, D., and Frantz, D., 2022, Improved burn severity estimation by using land surface phenology metrics and red edge information estimated from Landsat: International Journal of Applied Earth Observation and Geoinformation, v. 115, article 103126, at https://doi.org/10.1016/j.jag.2022.103126. |
Subalpine tree seedlings—Assessing aging methodology and drivers of establishment | Z. H. Schapira, C. S. Stevens-Rumann, D. Shorrock | 2021 | Schapira, Z.H., Stevens-Rumann, C.S., and Shorrock, D., 2021, Subalpine tree seedlings—Assessing aging methodology and drivers of establishment: Forest Ecology and Management, v. 497, article 119516, at https://doi.org/10.1016/j.foreco.2021.119516. |
Beetlemania—Is the bark worse than the bite? Rocky Mountain subalpine forests recover differently after spruce beetle outbreaks and wildfires | Z. Schapira, C. Stevens-Rumann, D. Shorrock, C. Hoffman, A. Chambers | 2021 | Schapira, Z., Stevens-Rumann, C., Shorrock, D., Hoffman, C., and Chambers, A., 2021, Beetlemania—Is the bark worse than the bite? Rocky Mountain subalpine forests recover differently after spruce beetle outbreaks and wildfires: Forest Ecology and Management, v. 482, article 118879, at https://doi.org/10.1016/j.foreco.2020.118879. |
Seedlings? The unexpected elders of understory trees, Final Report | Zoe Schapira, Camille Stevens-Rumann | 2020 | Schapira, Z., and Stevens-Rumann, C., 2020, Seedlings? The unexpected elders of understory trees, Final Report: Joint Fire Science Program JFSP PROJECT ID—19-1-01-59, 19 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2B9W0%20%20%0A. |
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Characterization and evaluation of controls on post-fire streamflow response across western US watersheds | S. Saxe, T. S. Hogue, L. Hay | 2018 | Saxe, S., Hogue, T.S., and Hay, L., 2018, Characterization and evaluation of controls on post-fire streamflow response across western US watersheds: Hydrology and Earth System Sciences, v. 22, no. 2, p. 1221–1237, at https://doi.org/10.5194/hess-22-1221-2018. |
The eco?evolutionary role of fire in shaping terrestrial ecosystems | F. Santos, J. K. Bailey, J. A. Schweitzer | 2023 | Santos, F., Bailey, J.K., and Schweitzer, J.A., 2023, The eco?evolutionary role of fire in shaping terrestrial ecosystems: Functional Ecology, v. 37, no. 8, p. 2090–2095, at https://doi.org/10.1111/1365-2435.14387. |
Phenology-based, remote sensing of post-burn disturbance windows in rangelands | J. B. Sankey, C. S. A. Wallace, S. Ravi | 2013 | Sankey, J.B., Wallace, C.S.A., and Ravi, S., 2013, Phenology-based, remote sensing of post-burn disturbance windows in rangelands: Ecological Indicators, v. 30, p. 35–44, at https://doi.org/10.1016/j.ecolind.2013.02.004. |
Climate, wildfire, and erosion ensemble foretells more sediment in western USA watersheds | J. B. Sankey, J. Kreitler, T. J. Hawbaker, J. L. Mcvay, M. E. Miller, E. R. Mueller, N. M. Vaillant, S. E. Lowe, T. T. Sankey | 2017 | Sankey, J.B., Kreitler, J., Hawbaker, T.J., Mcvay, J.L., Miller, M.E., Mueller, E.R., Vaillant, N.M., Lowe, S.E., and Sankey, T.T., 2017, Climate, wildfire, and erosion ensemble foretells more sediment in western USA watersheds: Geophysical Research Letters, v. 44, no. 17, p. 8884–8892, at https://doi.org/10.1002/2017gl073979. |
Precision gain versus effort with joint models using detection/non-detection and banding data | J. S. Sanderlin, W. M. Block, B. E. Strohmeyer, V. A. Saab, J. L. Ganey | 2019 | Sanderlin, J.S., Block, W.M., Strohmeyer, B.E., Saab, V.A., and Ganey, J.L., 2019, Precision gain versus effort with joint models using detection/non-detection and banding data: Ecology and Evolution, v. 9, no. 2, p. 804–817, at https://doi.org/10.1002/ece3.4825. |
Long-term post-wildfire correlates with avian community dynamics in ponderosa pine forests | Sanderlin, J.S., Block, W.M., Strohmeyer, B.E. | 2015 | Sanderlin, J.S., Block, W.M., and Strohmeyer, B.E., 2015, Long-term post-wildfire correlates with avian community dynamics in ponderosa pine forests, in 12th Biennial Conference of Research on the Colorado Plateau, Flagstaff, Ariz., 16–19 September 2013, Proceedings, U.S. Geological Survey Scientific Investigations Report 2015–5180: Reston, Va., U.S. Geological Survey, p. 89–101, at https://doi.org/10.3133/sir20155180. |
Physical and biogeochemical drivers of solute mobilization and flux through the critical zone after wildfire | R. A. Sánchez, T. Meixner, T. Roy, P. T. Ferré, M. Whitaker, J. Chorover | 2023 | Sánchez, R.A., Meixner, T., Roy, T., Ferré, P.T., Whitaker, M., and Chorover, J., 2023, Physical and biogeochemical drivers of solute mobilization and flux through the critical zone after wildfire: Frontiers in Water, v. 5, article 1148298, at https://doi.org/10.3389/frwa.2023.1148298. |
Where, when and how is the occurrence of large fires in La Pampa Province, Argentina—A remote sensing characterization | M. Sanchez, P. Baldassini, M. Á. Fischer, J. Zaffaroni, C. Di Bella | 2023 | Sanchez, M., Baldassini, P., Fischer, M.Á., Zaffaroni, J., and Di Bella, C., 2023, Where, when and how is the occurrence of large fires in La Pampa Province, Argentina—A remote sensing characterization: Ecologia Austral, v. 33, no. 1, p. 211–228, at https://doi.org/10.25260/EA.23.33.1.0.1972. |
Quantifying local fire regimes using the Landsat data-archive—A conceptual framework to derive detailed fire pattern metrics from pixel-level information | I. San-Miguel, D. W. Andison, N. C. Coops | 2018 | San-Miguel, I., Andison, D.W., and Coops, N.C., 2018, Quantifying local fire regimes using the Landsat data-archive—A conceptual framework to derive detailed fire pattern metrics from pixel-level information: International Journal of Digital Earth, v. 12, no. 5, p. 544–565, at https://doi.org/10.1080/17538947.2018.1464072. |
Wildfire trend analysis over the contiguous United States using remote sensing observations | J. Salguero, J. Li, A. Farahmand, J. T. Reager | 2020 | Salguero, J., Li, J., Farahmand, A., and Reager, J.T., 2020, Wildfire trend analysis over the contiguous United States using remote sensing observations: Remote Sensing, v. 12, no. 16, article 2565, at https://doi.org/10.3390/rs12162565. |
Fire history and vegetation data reveal ecological benefits of recent mixed-severity fires in the Cumberland Mountains, West Virginia, USA | T. Saladyga, K. A. Palmquist, C. M. Bacon | 2022 | Saladyga, T., Palmquist, K.A., and Bacon, C.M., 2022, Fire history and vegetation data reveal ecological benefits of recent mixed-severity fires in the Cumberland Mountains, West Virginia, USA: Fire Ecology, v. 18, no. 1, article 19, at https://doi.org/10.1186/s42408-022-00143-6. |
Low-severity wildfire shifts mixed conifer forests toward historical stand structure in Guadalupe Mountains National Park, Texas, USA | J. Sakulich, H. M. Poulos, R. G. Gatewood, K. A. Wogan, C. Marks, A. H. Taylor | 2022 | Sakulich, J., Poulos, H.M., Gatewood, R.G., Wogan, K.A., Marks, C., and Taylor, A.H., 2022, Low-severity wildfire shifts mixed conifer forests toward historical stand structure in Guadalupe Mountains National Park, Texas, USA: Fire, v. 5, no. 4, article 119, at https://doi.org/10.3390/fire5040119. |
Machine learning for modeling wildfire susceptibility at the state level—An example from Arkansas, USA | A. A. Saim, M. H. Aly | 2022 | Saim, A.A., and Aly, M.H., 2022, Machine learning for modeling wildfire susceptibility at the state level—An example from Arkansas, USA: Geographies, v. 2, no. 1, p. 31–47, at https://doi.org/10.3390/geographies2010004. |
Differences in land ownership, fire management objectives and source data matter—A reply to Hanson and Odion (2014) | H. D. Safford, J. D. Miller, B. M. Collins | 2015 | Safford, H.D., Miller, J.D., and Collins, B.M., 2015, Differences in land ownership, fire management objectives and source data matter—A reply to Hanson and Odion (2014): International Journal of Wildland Fire, v. 24, no. 2, p. 286–293, at https://doi.org/10.1071/WF14013. |
Temporal and spatial patterns of fire regime disruption in conifer forests of western North America | J. E. Sáenz-Ceja, M. E. Mendoza | in press | Sáenz-Ceja, J.E., and Mendoza, M.E., in press, Temporal and spatial patterns of fire regime disruption in conifer forests of western North America: Physical Geography, at https://doi.org/10.1080/02723646.2024.2331292. |
What is the color when black is burned? Quantifying (re)burn severity using field and satellite remote sensing indices | S. J. Saberi, B. J. Harvey | 2023 | Saberi, S.J., and Harvey, B.J., 2023, What is the color when black is burned? Quantifying (re)burn severity using field and satellite remote sensing indices: Fire Ecology, v. 19, no. 1, article 24, at https://doi.org/10.1186/s42408-023-00178-3. |
Contrasting characteristics of atmospheric rivers and their impacts on 2016 and 2020 wildfire seasons over the western United States | J.-M. Ryoo, T. Park | 2023 | Ryoo, J.-M., and Park, T., 2023, Contrasting characteristics of atmospheric rivers and their impacts on 2016 and 2020 wildfire seasons over the western United States: Environmental Research Letters, v. 18, no. 7, article 074010, at https://doi.org/10.1088/1748-9326/acd948. |
Evaluating the factors responsible for post-fire water quality response in forests of the western USA | A. J. Rust, S. Saxe, J. McCray, C. C. Rhoades, T. S. Hogue | 2019 | Rust, A.J., Saxe, S., McCray, J., Rhoades, C.C., and Hogue, T.S., 2019, Evaluating the factors responsible for post-fire water quality response in forests of the western USA: International Journal of Wildland Fire, v. 28, no. 10, p. 769–784, at https://doi.org/10.1071/Wf18191. |
Climate drives episodic conifer establishment after fire in dry ponderosa pine forests of the Colorado Front Range, USA | M. T. Rother, T. T. Veblen | 2017 | Rother, M.T., and Veblen, T.T., 2017, Climate drives episodic conifer establishment after fire in dry ponderosa pine forests of the Colorado Front Range, USA: Forests, v. 8, no. 5, article 159, at https://doi.org/10.3390/f8050159. |
Limited conifer regeneration following wildfires in dry ponderosa pine forests of the Colorado Front Range | M. T. Rother, T. T. Veblen | 2016 | Rother, M.T., and Veblen, T.T., 2016, Limited conifer regeneration following wildfires in dry ponderosa pine forests of the Colorado Front Range: Ecosphere, v. 7, no. 12, article e01594, at https://doi.org/10.1002/ecs2.1594. |
Targeting sagebrush (Artemisia Spp.) restoration following wildfire with greater sage-grouse (Centrocercus Urophasianus) nest selection and survival models | C. L. Roth, S. T. O’Neil, P. S. Coates, M. A. Ricca, D. A. Pyke, C. L. Aldridge, J. A. Heinrichs, S. P. Espinosa, D. J. Delehanty | 2022 | Roth, C.L., O’Neil, S.T., Coates, P.S., Ricca, M.A., Pyke, D.A., Aldridge, C.L., Heinrichs, J.A., Espinosa, S.P., and Delehanty, D.J., 2022, Targeting sagebrush (Artemisia Spp.) restoration following wildfire with greater sage-grouse (Centrocercus Urophasianus) nest selection and survival models: Environmental Management, v. 70, p. 288–306, at https://doi.org/10.1007/s00267-022-01649-0. |
Northern expansion is not compensating for southern declines in North American boreal forests | R. Rotbarth, E. H. Van Nes, M. Scheffer, J. U. Jepsen, O. P. L. Vindstad, C. Xu, M. Holmgren | 2023 | Rotbarth, R., Van Nes, E.H., Scheffer, M., Jepsen, J.U., Vindstad, O.P.L., Xu, C., and Holmgren, M., 2023, Northern expansion is not compensating for southern declines in North American boreal forests: Nature Communications, v. 14, no. 1, article 3373 at https://doi.org/10.1038/s41467-023-39092-2. |
Characterizing forest dynamics with Landsat-derived phenology curves | M. B. Rose, N. N. Nagle | 2021 | Rose, M.B., and Nagle, N.N., 2021, Characterizing forest dynamics with Landsat-derived phenology curves: Remote Sensing, v. 13, no. 2, article 267, at https://doi.org/10.3390/rs13020267. |
Long-term biocrust responses to wildfires in Washington, USA | H. T. Root, J. Chan, J. Ponzetti, D. A. Pyke, B. McCune | 2023 | Root, H.T., Chan, J., Ponzetti, J., Pyke, D.A., and McCune, B., 2023, Long-term biocrust responses to wildfires in Washington, USA: American Journal of Botany, v. 110, no. 12, article e16261, at https://doi.org/10.1002/ajb2.16261. |
Biotic soil crust community composition 12–16 years after wildfires in Idaho, U.S.A. | H. T. Root, J. C. Brinda, E. K. Dodson | 2018 | Root, H.T., Brinda, J.C., and Dodson, E.K., 2018, Biotic soil crust community composition 12–16 years after wildfires in Idaho, U.S.A.: The Bryologist, v. 121, no. 3, p. 286–296, at https://doi.org/10.1639/0007-2745-121.3.286. |
Recovery of biological soil crust richness and cover 12–16 years after wildfires in Idaho, USA | H. T. Root, J. C. Brinda, E. Kyle Dodson | 2017 | Root, H.T., Brinda, J.C., and Kyle Dodson, E., 2017, Recovery of biological soil crust richness and cover 12–16 years after wildfires in Idaho, USA: Biogeosciences, v. 14, no. 17, p. 3957–3969, at https://doi.org/10.5194/bg-14-3957-2017. |
Deterministic and stochastic processes lead to divergence in plant communities 25 years after the 1988 Yellowstone fires | W. H. Romme, T. G. Whitby, D. B. Tinker, M. G. Turner | 2016 | Romme, W.H., Whitby, T.G., Tinker, D.B., and Turner, M.G., 2016, Deterministic and stochastic processes lead to divergence in plant communities 25 years after the 1988 Yellowstone fires: Ecological Monographs, v. 86, no. 3, p. 327–351, at https://doi.org/10.1002/ecm.1220. |
Postwildfire measurement of soil physical and hydraulic properties at selected sampling sites in the 2011 Las Conchas wildfire burn scar, Jemez Mountains, north-central New Mexico | Romero, Orlando C., Ebel, Brian A., Martin, Deborah A., Buchan, Katie W., Jornigan, Alanna D. | 2018 | Romero, O.C., Ebel, B.A., Martin, D.A., Buchan, K.W., and Jornigan, A.D., 2018, Postwildfire measurement of soil physical and hydraulic properties at selected sampling sites in the 2011 Las Conchas wildfire burn scar, Jemez Mountains, north-central New Mexico: Reston, Va., U.S. Geological Survey Scientific Investigations Report 2018–5028, 48 p., at https://doi.org/10.3133/sir20185028. |
Quantifying fire-wide carbon emissions in interior Alaska using field measurements and Landsat imagery | B. M. Rogers, S. Veraverbeke, G. Azzari, C. I. Czimczik, S. R. Holden, G. O. Mouteva, F. Sedano, K. K. Treseder, J. T. Randerson | 2014 | Rogers, B.M., Veraverbeke, S., Azzari, G., Czimczik, C.I., Holden, S.R., Mouteva, G.O., Sedano, F., Treseder, K.K., and Randerson, J.T., 2014, Quantifying fire-wide carbon emissions in interior Alaska using field measurements and Landsat imagery: Journal of Geophysical Research—Biogeosciences, v. 119, no. 8, p. 1608–1629, at https://doi.org/10.1002/2014JG002657. |
SCaMF-RM—A fused high-resolution land cover product of the Rocky Mountains | N. Rodríguez-Jeangros, A. S. Hering, T. Kaiser, J. E. McCray | 2017 | Rodríguez-Jeangros, N., Hering, A.S., Kaiser, T., and McCray, J.E., 2017, SCaMF-RM—A fused high-resolution land cover product of the Rocky Mountains: Remote Sensing, v. 9, no. 10, article 1015, at https://doi.org/10.3390/rs9101015. |
Analysis of anthropogenic, climatological, and morphological influences on dissolved organic matter in Rocky Mountain streams | N. Rodríguez-Jeangros, A. Hering, J. McCray | 2018 | Rodríguez-Jeangros, N., Hering, A., and McCray, J., 2018, Analysis of anthropogenic, climatological, and morphological influences on dissolved organic matter in Rocky Mountain streams: Water, v. 10, no. 4, article 534, at https://doi.org/10.3390/w10040534. |
Using multi-decadal satellite records to identify environmental drivers of fire severity across vegetation types | D. Rodriguez-Cubillo, G. J. Jordan, G. J. Williamson | 2022 | Rodriguez-Cubillo, D., Jordan, G.J., and Williamson, G.J., 2022, Using multi-decadal satellite records to identify environmental drivers of fire severity across vegetation types: Remote Sensing in Earth Systems Sciences, v. 5, no. 3, p. 165–184, at https://doi.org/10.1007/s41976-022-00070-9. |
Wildfire activity and land use drove 20th-century changes in forest cover in the Colorado Front Range | K. C. Rodman, T. T. Veblen, S. Saraceni, T. B. Chapman | 2019 | Rodman, K.C., Veblen, T.T., Saraceni, S., and Chapman, T.B., 2019, Wildfire activity and land use drove 20th-century changes in forest cover in the Colorado Front Range: Ecosphere, v. 10, no. 2, article e02594, at https://doi.org/10.1002/ecs2.2594. |
Limitations to recovery following wildfire in dry forests of southern Colorado and northern New Mexico, USA | K. C. Rodman, T. T. Veblen, T. B. Chapman, M. T. Rother, A. P. Wion, M. D. Redmond | 2020 | Rodman, K.C., Veblen, T.T., Chapman, T.B., Rother, M.T., Wion, A.P., and Redmond, M.D., 2020, Limitations to recovery following wildfire in dry forests of southern Colorado and northern New Mexico, USA: Ecological Applications, v. 30, no. 1, article e02001, at https://doi.org/10.1002/eap.2001. |
A changing climate is snuffing out post-fire recovery in montane forests | K. C. Rodman, T. T. Veblen, M. A. Battaglia, M. E. Chambers, P. J. Fornwalt, Z. A. Holden, T. E. Kolb, J. R. Ouzts, M. T. Rother | 2020 | Rodman, K.C., Veblen, T.T., Battaglia, M.A., Chambers, M.E., Fornwalt, P.J., Holden, Z.A., Kolb, T.E., Ouzts, J.R., and Rother, M.T., 2020, A changing climate is snuffing out post-fire recovery in montane forests: Global Ecology and Biogeography, v. 29, no. 11, p. 2039–2051, at https://doi.org/10.1111/geb.13174. |
A trait-based approach to assessing resistance and resilience to wildfire in two iconic North American conifers | K. C. Rodman, T. T. Veblen, R. A. Andrus, N. J. Enright, J. B. Fontaine, A. D. Gonzalez, M. D. Redmond, A. P. Wion | 2020 | Rodman, K.C., Veblen, T.T., Andrus, R.A., Enright, N.J., Fontaine, J.B., Gonzalez, A.D., Redmond, M.D., and Wion, A.P., 2020, A trait-based approach to assessing resistance and resilience to wildfire in two iconic North American conifers: Journal of Ecology, v. 109, no. 1, p. 313–326, at https://doi.org/10.1111/1365-2745.13480. |
Refuge-yeah or refuge-nah? Predicting locations of forest resistance and recruitment in a fiery world | K. C. Rodman, K. T. Davis, S. A. Parks, T. B. Chapman, J. D. Coop, J. M. Iniguez, J. P. Roccaforte, A. J. Sánchez Meador, J. D. Springer, C. S. Stevens-Rumann, M. T. Stoddard, A. E. M. Waltz, T. N. Wasserman | 2023 | Rodman, K.C., Davis, K.T., Parks, S.A., Chapman, T.B., Coop, J.D., Iniguez, J.M., Roccaforte, J.P., Sánchez Meador, A.J., Springer, J.D., et al., 2023, Refuge-yeah or refuge-nah? Predicting locations of forest resistance and recruitment in a fiery world: Global Change Biology, v. 29, no. 24, p. 7029–7050, at https://doi.org/10.1111/gcb.16939. |
Patterns and drivers of recent land cover change on two trailing-edge forest landscapes | K. C. Rodman, J. E. Crouse, J. J. Donager, D. W. Huffman, A. J. Sánchez Meador | 2022 | Rodman, K.C., Crouse, J.E., Donager, J.J., Huffman, D.W., and Sánchez Meador, A.J., 2022, Patterns and drivers of recent land cover change on two trailing-edge forest landscapes: Forest Ecology and Management, v. 521, article 120449, at https://doi.org/10.1016/j.foreco.2022.120449. |
Rocky Mountain forests are poised to recover following bark beetle outbreaks but with altered composition | K. C. Rodman, R. A. Andrus, A. R. Carlson, T. A. Carter, T. B. Chapman, J. D. Coop, P. J. Fornwalt, N. S. Gill, B. J. Harvey, A. E. Hoffman, K. C. Kelsey, D. Kulakowski, D. C. Laughlin, J. E. Morris, J. F. Negrón, K. M. Nigro, G. S. Pappas, M. D. Redmond, C. C. Rhoades, M. E. Rocca, Z. H. Schapira, J. S. Sibold, C. S. Stevens-Rumann, T. T. Veblen, J. Wang, X. Zhang, S. J. Hart | 2022 | Rodman, K.C., Andrus, R.A., Carlson, A.R., Carter, T.A., Chapman, T.B., Coop, J.D., Fornwalt, P.J., Gill, N.S., Harvey, B.J., et al., 2022, Rocky Mountain forests are poised to recover following bark beetle outbreaks but with altered composition: Journal of Ecology, v. 110, no. 12, p. 2929–2949, at https://doi.org/10.1111/1365-2745.13999. |
Effects of bark beetle outbreaks on forest landscape pattern in the Southern Rocky Mountains, U.S.A. | K. C. Rodman, R. A. Andrus, C. L. Butkiewicz, T. B. Chapman, N. S. Gill, B. J. Harvey, D. Kulakowski, N. J. Tutland, T. T. Veblen, S. J. Hart | 2021 | Rodman, K.C., Andrus, R.A., Butkiewicz, C.L., Chapman, T.B., Gill, N.S., Harvey, B.J., Kulakowski, D., Tutland, N.J., Veblen, T.T., and Hart, S.J., 2021, Effects of bark beetle outbreaks on forest landscape pattern in the Southern Rocky Mountains, U.S.A.: Remote Sensing, v. 13, no. 6, article 1089, at https://doi.org/10.3390/rs13061089. |
The late Holocene history of Lake Cahuilla—Two thousand years of repeated fillings within the Salton Trough, Imperial Valley, California | T. K. Rockwell, A. J. Meltzner, E. C. Haaker, D. Madugo | 2022 | Rockwell, T.K., Meltzner, A.J., Haaker, E.C., and Madugo, D., 2022, The late Holocene history of Lake Cahuilla—Two thousand years of repeated fillings within the Salton Trough, Imperial Valley, California: Quaternary Science Reviews, v. 282, article 107456, at https://doi.org/10.1016/j.quascirev.2022.107456. |
Differential impacts of wildfire on the population dynamics of an old-forest species | J. T. Rockweit, A. B. Franklin, P. C. Carlson | 2017 | Rockweit, J.T., Franklin, A.B., and Carlson, P.C., 2017, Differential impacts of wildfire on the population dynamics of an old-forest species: Ecology, v. 98, no. 6, p. 1574–1582, at https://doi.org/10.1002/ecy.1805. |
Estimating evapotranspiration change due to forest treatment and fire at the basin scale in the Sierra Nevada, California | J. W. Roche, M. L. Goulden, R. C. Bales | 2018 | Roche, J.W., Goulden, M.L., and Bales, R.C., 2018, Estimating evapotranspiration change due to forest treatment and fire at the basin scale in the Sierra Nevada, California: Ecohydrology, v. 11, no. 7, article e1978, at https://doi.org/10.1002/eco.1978. |
A century of changing flows—Forest management changed flow magnitudes and warming advanced the timing of flow in a southwestern US river | M. D. Robles, D. S. Turner, J. A. Haney | 2017 | Robles, M.D., Turner, D.S., and Haney, J.A., 2017, A century of changing flows—Forest management changed flow magnitudes and warming advanced the timing of flow in a southwestern US river: PLoS ONE, v. 12, no. 11, article e0187875, at https://doi.org/10.1371/journal.pone.0187875. |
Effects of climate variability and accelerated forest thinning on watershed-scale runoff in southwestern USA ponderosa pine forests | M. D. Robles, R. M. Marshall, F. O'Donnell, E. B. Smith, J. A. Haney, D. F. Gori | 2014 | Robles, M.D., Marshall, R.M., O'Donnell, F., Smith, E.B., Haney, J.A., and Gori, D.F., 2014, Effects of climate variability and accelerated forest thinning on watershed-scale runoff in southwestern USA ponderosa pine forests: PLoS ONE, v. 9, no. 10, article A1819, at https://doi.org/10.1371/journal.pone.0111092. |
A geospatial dataset providing first-order indicators of wildfire risks to water supply in Canada and Alaska | F. N. Robinne | 2020 | Robinne, F.N., 2020, A geospatial dataset providing first-order indicators of wildfire risks to water supply in Canada and Alaska: Data Brief, v. 29, article 105171, at https://doi.org/10.1016/j.dib.2020.105171. |
A synthesis of post-fire Burned Area Reports from 1972 to 2009 for western US Forest Service lands—Trends in wildfire characteristics and post-fire stabilisation treatments and expenditures | P. R. Robichaud, H. Rhee, S. A. Lewis | 2014 | Robichaud, P.R., Rhee, H., and Lewis, S.A., 2014, A synthesis of post-fire Burned Area Reports from 1972 to 2009 for western US Forest Service lands—Trends in wildfire characteristics and post-fire stabilisation treatments and expenditures: International Journal of Wildland Fire, v. 23, no. 7, p. 929–944, at https://doi.org/10.1071/WF13192. |
Leveraging the potential of nature to meet net zero greenhouse gas emissions in Washington State | J. C. Robertson, K. V. Randrup, E. R. Howe, M. J. Case, P. S. Levin | 2021 | Robertson, J.C., Randrup, K.V., Howe, E.R., Case, M.J., and Levin, P.S., 2021, Leveraging the potential of nature to meet net zero greenhouse gas emissions in Washington State: PeerJ, v. 9, article e11802, at https://doi.org/10.7717/peerj.11802. |
Tracking spatial regimes in animal communities—Implications for resilience-based management | C. P. Roberts, D. R. Uden, C. R. Allen, D. G. Angeler, L. A. Powell, B. W. Allred, M. O. Jones, J. D. Maestas, D. Twidwell | 2022 | Roberts, C.P., Uden, D.R., Allen, C.R., Angeler, D.G., Powell, L.A., Allred, B.W., Jones, M.O., Maestas, J.D., and Twidwell, D., 2022, Tracking spatial regimes in animal communities—Implications for resilience-based management: Ecological Indicators, v. 136, article 108567, at https://doi.org/10.1016/j.ecolind.2022.108567. |
Fire legacies in eastern ponderosa pine forests | C. P. Roberts, V. M. Donovan, C. L. Wonkka, L. A. Powell, C. R. Allen, D. G. Angeler, D. A. Wedin, D. Twidwell | 2019 | Roberts, C.P., Donovan, V.M., Wonkka, C.L., Powell, L.A., Allen, C.R., Angeler, D.G., Wedin, D.A., and Twidwell, D., 2019, Fire legacies in eastern ponderosa pine forests: Ecology and Evolution, v. 9, no. 4, p. 1869–1879, at https://doi.org/10.1002/ece3.4879. |
Fire legacies, heterogeneity, and the importance of mixed-severity fire in ponderosa pine savannas | C. P. Roberts, V. M. Donovan, S. M. Nodskov, E. B. Keele, C. R. Allen, D. A. Wedin, D. Twidwell | 2020 | Roberts, C.P., Donovan, V.M., Nodskov, S.M., Keele, E.B., Allen, C.R., Wedin, D.A., and Twidwell, D., 2020, Fire legacies, heterogeneity, and the importance of mixed-severity fire in ponderosa pine savannas: Forest Ecology and Management, v. 459, article 117853, at https://doi.org/10.1016/j.foreco.2019.117853. |
Patterns and trends in burned area and fire severity from 1984 to 2010 in the Sierra de San Pedro Martir, Baja California, Mexico | H. Rivera-Huerta, H. D. Safford, J. D. Miller | 2016 | Rivera-Huerta, H., Safford, H.D., and Miller, J.D., 2016, Patterns and trends in burned area and fire severity from 1984 to 2010 in the Sierra de San Pedro Martir, Baja California, Mexico: Fire Ecology, v. 12, no. 1, p. 52–72, at https://doi.org/10.4996/fireecology.1201052. |
A model-based framework to evaluate alternative wildfire suppression strategies | K. L. Riley, M. P. Thompson, J. H. Scott, J. W. Gilbertson-Day | 2018 | Riley, K.L., Thompson, M.P., Scott, J.H., and Gilbertson-Day, J.W., 2018, A model-based framework to evaluate alternative wildfire suppression strategies: Resources, v. 7, no. 1, article 4, at https://doi.org/10.3390/resources7010004. |
The relationship of large fire occurrence with drought and fire danger indices in the western USA, 1984–2008—The role of temporal scale | K. L. Riley, J. T. Abatzoglou, I. C. Grenfell, A. E. Klene, F. A. Heinsch | 2013 | Riley, K.L., Abatzoglou, J.T., Grenfell, I.C., Klene, A.E., and Heinsch, F.A., 2013, The relationship of large fire occurrence with drought and fire danger indices in the western USA, 1984–2008—The role of temporal scale: International Journal of Wildland Fire, v. 22, no. 7, p. 894–909, at https://doi.org/10.1071/WF12149. |
Assessing predictive services' 7-day fire potential outlook | Riley, Karin, Stonesifer, Crystal, Calkin, Dave, Preisler, Haiganoush | 2015 | Riley, K., Stonesifer, C., Calkin, D., and Preisler, H., 2015, Assessing predictive services' 7-day fire potential outlook, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 188–195, at https://www.fs.usda.gov/treesearch/pubs/49443. |
Influence of management and precipitation on carbon fluxes in great plains grasslands | M. Rigge, B. Wylie, L. Zhang, S. P. Boyte | 2013 | Rigge, M., Wylie, B., Zhang, L., and Boyte, S.P., 2013, Influence of management and precipitation on carbon fluxes in great plains grasslands: Ecological Indicators, v. 34, no. 0, p. 590–599, at https://doi.org/10.1016/j.ecolind.2013.06.028. |
Monitoring the status of forests and rangelands in the western United States using ecosystem performance anomalies | M. Rigge, B. Wylie, Y. Gu, J. Belnap, K. Phuyal, L. Tieszen | 2013 | Rigge, M., Wylie, B., Gu, Y., Belnap, J., Phuyal, K., and Tieszen, L., 2013, Monitoring the status of forests and rangelands in the western United States using ecosystem performance anomalies: International Journal of Remote Sensing, v. 34, no. 11, p. 4049–4068, at https://doi.org/10.1080/01431161.2013.772311. |
Projected change in rangeland fractional component cover across the sagebrush biome under climate change through 2085 | M. Rigge, H. Shi, K. Postma | 2021 | Rigge, M., Shi, H., and Postma, K., 2021, Projected change in rangeland fractional component cover across the sagebrush biome under climate change through 2085: Ecosphere, v. 12, no. 6, article e03538, at https://doi.org/10.1002/ecs2.3538. |
Long-term trajectories of fractional component change in the northern Great Basin, USA | M. Rigge, H. Shi, C. Homer, P. Danielson, B. Granneman | 2019 | Rigge, M., Shi, H., Homer, C., Danielson, P., and Granneman, B., 2019, Long-term trajectories of fractional component change in the northern Great Basin, USA: Ecosphere, v. 10, no. 6, article e02762, at https://doi.org/10.1002/ecs2.2762. |
Ecological potential fractional component cover based on long-term satellite observations across the western United States | M. Rigge, D. Meyer, B. Bunde | 2021 | Rigge, M., Meyer, D., and Bunde, B., 2021, Ecological potential fractional component cover based on long-term satellite observations across the western United States: Ecological Indicators, v. 133, article 108447, at https://doi.org/10.1016/j.ecolind.2021.108447. |
Rangeland fractional components across the western United States from 1985 to 2018 | M. Rigge, C. Homer, H. Shi, D. Meyer, B. Bunde, B. Granneman, K. Postma, P. Danielson, A. Case, G. Xian | 2021 | Rigge, M., Homer, C., Shi, H., Meyer, D., Bunde, B., Granneman, B., Postma, K., Danielson, P., Case, A., and Xian, G., 2021, Rangeland fractional components across the western United States from 1985 to 2018: Remote Sensing, v. 13, no. 4, article 813, at https://doi.org/10.3390/rs13040813. |
Quantifying western U.S. rangelands as fractional components with multi-resolution remote sensing and in situ data | M. Rigge, C. Homer, L. Cleeves, D. K. Meyer, B. Bunde, H. Shi, G. Xian, S. Schell, M. Bobo | 2020 | Rigge, M., Homer, C., Cleeves, L., Meyer, D.K., Bunde, B., Shi, H., Xian, G., Schell, S., and Bobo, M., 2020, Quantifying western U.S. rangelands as fractional components with multi-resolution remote sensing and in situ data: Remote Sensing, v. 12, no. 3, article 412, at https://doi.org/10.3390/rs12030412. |
A potential framework for allocating National Park Service budgets | D. B. Rideout, Y. Wei, N. Kernohan, A. G. Kirsch | 2022 | Rideout, D.B., Wei, Y., Kernohan, N., and Kirsch, A.G., 2022, A potential framework for allocating National Park Service budgets: Frontiers in Forests and Global Change, v. 5, article 716569, at https://doi.org/10.3389/ffgc.2022.716569. |
Wildfires increase concentrations of hazardous air pollutants in downwind communities | R. B. Rice, K. Boaggio, N. E. Olson, K. M. Foley, C. P. Weaver, J. D. Sacks, S. R. McDow, A. L. Holder, S. D. LeDuc | 2023 | Rice, R.B., Boaggio, K., Olson, N.E., Foley, K.M., Weaver, C.P., Sacks, J.D., McDow, S.R., Holder, A.L., and LeDuc, S.D., 2023, Wildfires increase concentrations of hazardous air pollutants in downwind communities: Environmental Science & Technology, v. 57, no. 50, p. 21235–21248, at https://doi.org/10.1021/acs.est.3c04153. |
A conservation planning tool for greater sage-grouse using indices of species distribution, resilience, and resistance | M. A. Ricca, P. S. Coates, K. B. Gustafson, B. E. Brussee, J. C. Chambers, S. P. Espinosa, S. C. Gardner, S. Lisius, P. Ziegler, D. J. Delehanty, M. L. Casazza | 2018 | Ricca, M.A., Coates, P.S., Gustafson, K.B., Brussee, B.E., Chambers, J.C., Espinosa, S.P., Gardner, S.C., Lisius, S., Ziegler, P., et al., 2018, A conservation planning tool for greater sage-grouse using indices of species distribution, resilience, and resistance: Ecological Applications, v. 28, no. 4, p. 878–896, at https://doi.org/10.1002/eap.1690. |
Integrating ecosystem resilience and resistance into decision support tools for multi-scale population management of a sagebrush indicator species | M. A. Ricca, P. S. Coates | 2020 | Ricca, M.A., and Coates, P.S., 2020, Integrating ecosystem resilience and resistance into decision support tools for multi-scale population management of a sagebrush indicator species: Frontiers in Ecology and Evolution, v. 7, article 493, at https://doi.org/10.3389/fevo.2019.00493. |
Modeling herbaceous biomass for grazing and fire risk management | E. C. Rhodes, D. R. Tolleson, J. P. Angerer | 2022 | Rhodes, E.C., Tolleson, D.R., and Angerer, J.P., 2022, Modeling herbaceous biomass for grazing and fire risk management: Land, v. 11, no. 10, article 1769, at https://doi.org/10.3390/land11101769. |
Use of geostatistical models to evaluate landscape and stream network controls on post-fire stream nitrate concentrations | A. E. Rhea, T. P. Covino, C. C. Rhoades, A. C. Brooks | 2022 | Rhea, A.E., Covino, T.P., Rhoades, C.C., and Brooks, A.C., 2022, Use of geostatistical models to evaluate landscape and stream network controls on post-fire stream nitrate concentrations: Hydrological Processes, v. 36, no. 9, article e14689, at https://doi.org/10.1002/hyp.14689. |
Reduced N-limitation and increased in-stream productivity of autotrophic biofilms 5 and 15 years after severe wildfire | A. E. Rhea, T. P. Covino, C. C. Rhoades | 2021 | Rhea, A.E., Covino, T.P., and Rhoades, C.C., 2021, Reduced N-limitation and increased in-stream productivity of autotrophic biofilms 5 and 15 years after severe wildfire: Journal of Geophysical Research—Biogeosciences, v. 126, no. 9, article e2020JG006095, at https://doi.org/10.1029/2020JG006095. |
Wildfire-induced shifts in groundwater discharge to streams identified with paired air and stream water temperature analyses | D. M. Rey, M. A. Briggs, M. A. Walvoord, B. A. Ebel | 2023 | Rey, D.M., Briggs, M.A., Walvoord, M.A., and Ebel, B.A., 2023, Wildfire-induced shifts in groundwater discharge to streams identified with paired air and stream water temperature analyses: Journal of Hydrology, v. 619, article 129272, at https://doi.org/10.1016/j.jhydrol.2023.129272. |
A spectral–spatial method for mapping fire severity using morphological attribute profiles | X. Ren, X. Yu, Y. Wang | 2023 | Ren, X., Yu, X., and Wang, Y., 2023, A spectral–spatial method for mapping fire severity using morphological attribute profiles: Remote Sensing, v. 15, no. 3, article 699, at https://doi.org/10.3390/rs15030699. |
Bark beetle effects on fire regimes depend on underlying fuel modifications in semiarid systems | J. Ren, E. J. Hanan, J. A. Hicke, C. A. Kolden, J. T. Abatzoglou, C. N. L. Tague, R. R. Bart, M. C. Kennedy, M. Liu, J. C. Adam | 2023 | Ren, J., Hanan, E.J., Hicke, J.A., Kolden, C.A., Abatzoglou, J.T., Tague, C.N.L., Bart, R.R., Kennedy, M.C., Liu, M., and Adam, J.C., 2023, Bark beetle effects on fire regimes depend on underlying fuel modifications in semiarid systems: Journal of Advances in Modeling Earth Systems, v. 15, no. 1, article e2022MS003073, at https://doi.org/10.1029/2022MS003073. |
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Improving fire severity analysis in Mediterranean environments—A comparative study of eeMETRIC and SSEBop Landsat-based evapotranspiration models | C. Quintano, A. Fernández-Manso, J. M. Fernández-Guisuraga, D. A. Roberts | 2024 | Quintano, C., Fernández-Manso, A., Fernández-Guisuraga, J.M., and Roberts, D.A., 2024, Improving fire severity analysis in Mediterranean environments—A comparative study of eeMETRIC and SSEBop Landsat-based evapotranspiration models: Remote Sensing, v. 16, no. 2, article 361, at https://doi.org/10.3390/rs16020361. |
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The impacts of wildfire characteristics and employment on the adaptive management strategies in the Intermountain West | L. Prudencio, R. Choi, E. Esplin, M. Ge, N. Gillard, J. Haight, P. Belmont, C. Flint | 2018 | Prudencio, L., Choi, R., Esplin, E., Ge, M., Gillard, N., Haight, J., Belmont, P., and Flint, C., 2018, The impacts of wildfire characteristics and employment on the adaptive management strategies in the Intermountain West: Fire, v. 1, no. 3, article 46, at https://doi.org/10.3390/fire1030046. |
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Modeling of fire spread in sagebrush steppe using FARSITE—An approach to improving input data and simulation accuracy | S. Price, M. J. Germino | 2022 | Price, S., and Germino, M.J., 2022, Modeling of fire spread in sagebrush steppe using FARSITE—An approach to improving input data and simulation accuracy: Fire Ecology, v. 18, no. 1, article 23, at https://doi.org/10.1186/s42408-022-00147-2. |
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Multiple wildfires with minimal consequences—Low-severity wildfire effects on West Texas piñon-juniper woodlands | H. M. Poulos, C. M. Reemts, K. A. Wogan, J. P. Karges, R. G. Gatewood | 2020 | Poulos, H.M., Reemts, C.M., Wogan, K.A., Karges, J.P., and Gatewood, R.G., 2020, Multiple wildfires with minimal consequences—Low-severity wildfire effects on West Texas piñon-juniper woodlands: Forest Ecology and Management, v. 473, article 118293, at https://doi.org/10.1016/j.foreco.2020.118293. |
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Wildfire severity and vegetation recovery drive post?fire evapotranspiration in a southwestern pine?oak forest, Arizona, USA | H. M. Poulos, A. M. Barton, G. W. Koch, T. E. Kolb, A. E. Thode, M. Disney, S. Levick | 2021 | Poulos, H.M., Barton, A.M., Koch, G.W., Kolb, T.E., Thode, A.E., Disney, M., and Levick, S., 2021, Wildfire severity and vegetation recovery drive post?fire evapotranspiration in a southwestern pine?oak forest, Arizona, USA: Remote Sensing in Ecology and Conservation, v. 7, no. 4, p. 579–591, at https://doi.org/10.1002/rse2.210. |
Vegetation regrowth following wildfires in the Santa Cruz Mountains of northern California monitored using Landsat satellite image analysis | C. S. Potter | 2016 | Potter, C.S., 2016, Vegetation regrowth following wildfires in the Santa Cruz Mountains of northern California monitored using Landsat satellite image analysis: Open Journal of Forestry, v. 6, no. 2, p. 82–93, at https://doi.org/10.4236/ojf.2016.62008. |
Wildfire effects on permafrost and soil moisture in spruce forests of interior Alaska | C. Potter, C. Hugny | 2018 | Potter, C., and Hugny, C., 2018, Wildfire effects on permafrost and soil moisture in spruce forests of interior Alaska: Journal of Forestry Research, v. 31, no. 2, p. 553–563, at https://doi.org/10.1007/s11676-018-0831-2. |
Controls on land surface temperature in deserts of southern California derived from MODIS satellite time series analysis, 2000 to 2018 | C. Potter, D. Coppernoll-Houston | 2019 | Potter, C., and Coppernoll-Houston, D., 2019, Controls on land surface temperature in deserts of southern California derived from MODIS satellite time series analysis, 2000 to 2018: Climate, v. 7, no. 2, article 32, at https://doi.org/10.3390/cli7020032. |
Changes in vegetation phenology and productivity in Alaska over the past two decades | C. Potter, O. Alexander | 2020 | Potter, C., and Alexander, O., 2020, Changes in vegetation phenology and productivity in Alaska over the past two decades: Remote Sensing, v. 12, no. 10, article 1546, at https://doi.org/10.3390/rs12101546. |
Changes in vegetation cover and snowmelt timing in the Noatak National Preserve of northwestern Alaska estimated from MODIS and Landsat satellite image analysis | C. Potter, O. Alexander | 2019 | Potter, C., and Alexander, O., 2019, Changes in vegetation cover and snowmelt timing in the Noatak National Preserve of northwestern Alaska estimated from MODIS and Landsat satellite image analysis: European Journal of Remote Sensing, v. 52, no. 1, p. 542–556, at https://doi.org/10.1080/22797254.2019.1689852. |
Changes in vegetation cover of Yukon River drainages in interior Alaska—Estimated from MODIS greenness trends, 2000 to 2018 | C. Potter | 2020 | Potter, C., 2020, Changes in vegetation cover of Yukon River drainages in interior Alaska—Estimated from MODIS greenness trends, 2000 to 2018: Northwest Science, v. 94, no. 2, p. 160–175, at https://doi.org/10.3955/046.094.0206. |
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Shifts in vegetation cover of southern California deserts in response to recent climate variations | C. Potter | 2019 | Potter, C., 2019, Shifts in vegetation cover of southern California deserts in response to recent climate variations: Remote Sensing in Earth Systems Sciences, v. 2, p. 79–87, at https://doi.org/10.1007/s41976-019-00013-x. |
Changes in vegetation cover of Yellowstone National Park estimated from MODIS greenness trends, 2000 to 2018 | C. Potter | 2019 | Potter, C., 2019, Changes in vegetation cover of Yellowstone National Park estimated from MODIS greenness trends, 2000 to 2018: Remote Sensing in Earth Systems Sciences, v. 2, no. 2-3, p. 147–160, at https://doi.org/10.1007/s41976-019-00019-5. |
Changes in vegetation cover of the arctic national wildlife refuge estimated from MODIS greenness trends, 2000–18 | C. Potter | 2019 | Potter, C., 2019, Changes in vegetation cover of the arctic national wildlife refuge estimated from MODIS greenness trends, 2000–18: Earth Interactions, v. 23, article 4, at https://doi.org/10.1175/EI-D-18-0018.1. |
Recovery rates of Wetland Vegetation Greenness in severely burned ecosystems of Alaska derived from satellite image analysis | C. Potter | 2018 | Potter, C., 2018, Recovery rates of Wetland Vegetation Greenness in severely burned ecosystems of Alaska derived from satellite image analysis: Remote Sensing, v. 10, no. 9, article 1456, at https://doi.org/10.3390/rs10091456. |
Ecosystem carbon emissions from 2015 forest fires in interior Alaska | C. Potter | 2018 | Potter, C., 2018, Ecosystem carbon emissions from 2015 forest fires in interior Alaska: Carbon Balance and Management, v. 13, no. 1, article 2, at https://doi.org/10.1186/s13021-017-0090-0. |
Fire-climate history and landscape patterns of high burn severity areas on the California southern and central coast | C. Potter | 2017 | Potter, C., 2017, Fire-climate history and landscape patterns of high burn severity areas on the California southern and central coast: Journal of Coastal Conservation, v. 21, no. 3, p. 393–404, at https://doi.org/10.1007/s11852-017-0519-3. |
Vegetation cover change in Glacier National Park detected using 25 years of Landsat satellite image analysis | C. Potter | 2016 | Potter, C., 2016, Vegetation cover change in Glacier National Park detected using 25 years of Landsat satellite image analysis: Journal of Biodiversity Management & Forestry, v. 5, no. 1, p. 1–7, at https://doi.org/10.4172/2327-4417.1000156. |
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Assessment of the immediate impacts of the 2013–2014 drought on ecosystems of the California central coast | C. Potter | 2015 | Potter, C., 2015, Assessment of the immediate impacts of the 2013–2014 drought on ecosystems of the California central coast: Western North American Naturalist, v. 75, no. 2, p. 129–145, at https://doi.org/10.3398/064.075.0202. |
Weather factors associated with extremely large fires and fire growth days | B. E. Potter, D. McEvoy | 2021 | Potter, B.E., and McEvoy, D., 2021, Weather factors associated with extremely large fires and fire growth days: Earth Interactions, v. 25, no. 1, p. 160–176, at https://doi.org/10.1175/ei-d-21-0008.1. |
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A network analysis to identify forest merchantability limitations across the United States | R. Pokharel, G. S. Latta | 2020 | Pokharel, R., and Latta, G.S., 2020, A network analysis to identify forest merchantability limitations across the United States: Forest Policy and Economics, v. 116, article 102181, at https://doi.org/10.1016/j.forpol.2020.102181. |
Estimating climate-sensitive wildfire risk and tree mortality models for use in broad-scale U.S. forest carbon projections | R. Pokharel, G. Latta, S. B. Ohrel | 2023 | Pokharel, R., Latta, G., and Ohrel, S.B., 2023, Estimating climate-sensitive wildfire risk and tree mortality models for use in broad-scale U.S. forest carbon projections: Forests, v. 14, no. 2, article 302, at https://doi.org/10.3390/f14020302. |
A protocol for collecting burned area time series cross-check data | H. R. Podschwit, B. Potter, N. K. Larkin | 2022 | Podschwit, H.R., Potter, B., and Larkin, N.K., 2022, A protocol for collecting burned area time series cross-check data: Fire, v. 5, no. 5, article 153, at https://doi.org/10.3390/fire5050153. |
Multi-model forecasts of very-large fire occurences during the end of the 21st century | H. R. Podschwit, N. K. Larkin, E. A. Steel, A. Cullen, E. Alvarado | 2018 | Podschwit, H.R., Larkin, N.K., Steel, E.A., Cullen, A., and Alvarado, E., 2018, Multi-model forecasts of very-large fire occurences during the end of the 21st century: Climate, v. 6, no. 4, article 100, at https://doi.org/10.3390/cli6040100. |
Estimating wildfire growth from noisy and incomplete incident data using a state space model | H. Podschwit, P. Guttorp, N. Larkin, E. A. Steel | 2018 | Podschwit, H., Guttorp, P., Larkin, N., and Steel, E.A., 2018, Estimating wildfire growth from noisy and incomplete incident data using a state space model: Environmental and Ecological Statistics, v. 25, no. 3, p. 325–340, at https://doi.org/10.1007/s10651-018-0407-5. |
Patterns and trends in simultaneous wildfire activity in the United States from 1984 to 2015 | H. Podschwit, A. Cullen | 2020 | Podschwit, H., and Cullen, A., 2020, Patterns and trends in simultaneous wildfire activity in the United States from 1984 to 2015: International Journal of Wildland Fire, v. 29, no. 12, p. 1057–1071, at https://doi.org/10.1071/Wf19150. |
Fire refugia are robust across western US forested ecoregions, 1986–2021 | R. V. Platt, T. B. Chapman, J. K. Balch | 2023 | Platt, R.V., Chapman, T.B., and Balch, J.K., 2023, Fire refugia are robust across western US forested ecoregions, 1986–2021: Environmental Research Letters, v. 19, no. 1, article 014044, at https://doi.org/10.1088/1748-9326/ad11bf. |
Priorities and effectiveness in wildfire management—Evidence from fire spread in the western United States | A. J. Plantinga, R. Walsh, M. Wibbenmeyer | 2022 | Plantinga, A.J., Walsh, R., and Wibbenmeyer, M., 2022, Priorities and effectiveness in wildfire management—Evidence from fire spread in the western United States: Journal of the Association of Environmental and Resource Economists, v. 9, no. 4, p. 603–639, at https://doi.org/10.1086/719426. |
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A deep learning approach for mapping and dating burned areas using temporal sequences of satellite images | M. M. Pinto, R. Libonati, R. M. Trigo, I. F. Trigo, C. C. DaCamara | 2020 | Pinto, M.M., Libonati, R., Trigo, R.M., Trigo, I.F., and DaCamara, C.C., 2020, A deep learning approach for mapping and dating burned areas using temporal sequences of satellite images: ISPRS Journal of Photogrammetry and Remote Sensing, v. 160, p. 260–274, at https://doi.org/10.1016/j.isprsjprs.2019.12.014. |
Impactos de los incendios forestales de magnitud en áreas silvestres protegidas de Chile Central | J. F. Pinilla, M. C. Soto, R. M. N. Cerrillo | 2023 | Pinilla, J.F., Soto, M.C., and Cerrillo, R.M.N., 2023, Impactos de los incendios forestales de magnitud en áreas silvestres protegidas de Chile Central: Bosque, v. 44, no. 1, p. 83–95, at https://doi.org/10.4067/S0717-92002023000100083. |
The influence of fire history on soil nutrients and vegetation cover in mixed-severity fire regime forests of the eastern Olympic Peninsula, Washington, USA | M. R. A. Pingree, T. H. DeLuca | 2018 | Pingree, M.R.A., and DeLuca, T.H., 2018, The influence of fire history on soil nutrients and vegetation cover in mixed-severity fire regime forests of the eastern Olympic Peninsula, Washington, USA: Forest Ecology and Management, v. 422, p. 95–107, at https://doi.org/10.1016/j.foreco.2018.03.037. |
Adsorption capacity of wildfire-produced charcoal from Pacific Northwest forests | M. R. A. Pingree, E. E. DeLuca, D. T. Schwartz, T. H. DeLuca | 2016 | Pingree, M.R.A., DeLuca, E.E., Schwartz, D.T., and DeLuca, T.H., 2016, Adsorption capacity of wildfire-produced charcoal from Pacific Northwest forests: Geoderma, v. 283, p. 68–77, at https://doi.org/10.1016/j.geoderma.2016.07.016. |
Refining the cheatgrass-fire cycle in the Great Basin—Precipitation timing and fine fuel composition predict wildfire trends | D. S. Pilliod, J. L. Welty, R. S. Arkle | 2017 | Pilliod, D.S., Welty, J.L., and Arkle, R.S., 2017, Refining the cheatgrass-fire cycle in the Great Basin—Precipitation timing and fine fuel composition predict wildfire trends: Ecology and Evolution, v. 7, no. 19, p. 8126–8151, at https://doi.org/10.1002/ece3.3414. |
Consequential lightning-caused wildfires and the “let burn” narrative | B. M. Pietruszka, J. D. Young, K. C. Short, L. A. St. Denis, M. P. Thompson, D. E. Calkin | 2023 | Pietruszka, B.M., Young, J.D., Short, K.C., St. Denis, L.A., Thompson, M.P., and Calkin, D.E., 2023, Consequential lightning-caused wildfires and the “let burn” narrative: Fire Ecology, v. 19, no. 1, article 50, at https://doi.org/10.1186/s42408-023-00208-0. |
Use of random forests for modeling and mapping forest canopy fuels for fire behavior analysis in Lassen Volcanic National Park, California, USA | A. D. Pierce, C. A. Farris, A. H. Taylor | 2012 | Pierce, A.D., Farris, C.A., and Taylor, A.H., 2012, Use of random forests for modeling and mapping forest canopy fuels for fire behavior analysis in Lassen Volcanic National Park, California, USA: Forest Ecology and Management, v. 279, p. 77–89, at https://doi.org/10.1016/j.foreco.2012.05.010. |
1984–2010 trends in fire burn severity and area for the conterminous US | J. J. Picotte, B. Peterson, G. Meier, S. M. Howard | 2016 | Picotte, J.J., Peterson, B., Meier, G., and Howard, S.M., 2016, 1984–2010 trends in fire burn severity and area for the conterminous US: International Journal of Wildland Fire, v. 25, no. 4, p. 413–420, at https://doi.org/10.1071/Wf15039. |
LANDFIRE Remap prototype mapping effort—Developing a new framework for mapping vegetation classification, change, and structure | J. J. Picotte, D. Dockter, J. Long, B. Tolk, A. Davidson, B. Peterson | 2019 | Picotte, J.J., Dockter, D., Long, J., Tolk, B., Davidson, A., and Peterson, B., 2019, LANDFIRE Remap prototype mapping effort—Developing a new framework for mapping vegetation classification, change, and structure: Fire, v. 2, no. 2, article 35, at https://doi.org/10.3390/fire2020035. |
Determination of burn severity models ranging from regional to national scales for the conterminous United States | J. J. Picotte, C. A. Cansler, C. A. Kolden, J. A. Lutz, C. Key, N. C. Benson, K. M. Robertson | 2021 | Picotte, J.J., Cansler, C.A., Kolden, C.A., Lutz, J.A., Key, C., Benson, N.C., and Robertson, K.M., 2021, Determination of burn severity models ranging from regional to national scales for the conterminous United States: Remote Sensing of Environment, v. 263, article 112569, at https://doi.org/10.1016/j.rse.2021.112569. |
Changes to the Monitoring Trends in Burn Severity program mapping production procedures and data products | J. J. Picotte, K. Bhattarai, D. Howard, J. Lecker, J. Epting, B. Quayle, N. Benson, K. Nelson | 2020 | Picotte, J.J., Bhattarai, K., Howard, D., Lecker, J., Epting, J., Quayle, B., Benson, N., and Nelson, K., 2020, Changes to the Monitoring Trends in Burn Severity program mapping production procedures and data products: Fire Ecology, v. 16, no. 1, article 16, at https://doi.org/10.1186/s42408-020-00076-y. |
Digital mapping of vegetative great groups to inform management strategies | L. Phipps, T. K. Stringham | 2024 | Phipps, L., and Stringham, T.K., 2024, Digital mapping of vegetative great groups to inform management strategies: Rangeland Ecology & Management, v. 94, p. 7–19, at https://doi.org/10.1016/j.rama.2024.01.006. |
Association between wildfires and coccidioidomycosis incidence in California, 2000–2018—A synthetic control analysis | S. Phillips, I. Jones, G. Sondermyer-Cooksey, A. T. Yu, A. K. Heaney, B. Zhou, A. Bhattachan, A. K. Weaver, S. K. Campo, W. Mgbara, R. Wagner, J. Taylor, D. Lettenmaier, G. S. Okin, S. Jain, D. Vugia, J. V. Remais, J. R. Head | 2023 | Phillips, S., Jones, I., Sondermyer-Cooksey, G., Yu, A.T., Heaney, A.K., Zhou, B., Bhattachan, A., Weaver, A.K., Campo, S.K., et al., 2023, Association between wildfires and coccidioidomycosis incidence in California, 2000–2018—A synthetic control analysis: Environmental Epidemiology, v. 7, no. 4, article e254, at https://doi.org/10.1097/ee9.0000000000000254. |
Using Landsat-derived disturbance and recovery history and lidar to map forest biomass dynamics | D. Pflugmacher, W. B. Cohen, R. E. Kennedy, Z. Yang | 2014 | Pflugmacher, D., Cohen, W.B., Kennedy, R.E., and Yang, Z., 2014, Using Landsat-derived disturbance and recovery history and lidar to map forest biomass dynamics: Remote Sensing of Environment, v. 151, p. 124–137, at https://doi.org/10.1016/j.rse.2013.05.033. |
Evaluating and monitoring forest fuel treatments using remote sensing applications in Arizona, U.S.A. | R. E. Petrakis, M. L. Villarreal, Z. Wu, R. Hetzler, B. R. Middleton, L. M. Norman | 2018 | Petrakis, R.E., Villarreal, M.L., Wu, Z., Hetzler, R., Middleton, B.R., and Norman, L.M., 2018, Evaluating and monitoring forest fuel treatments using remote sensing applications in Arizona, U.S.A.: Forest Ecology and Management, v. 413, p. 48–61, at https://doi.org/10.1016/j.foreco.2018.01.036. |
Riparian vegetation response amid variable climate conditions across the Upper Gila River watershed—Informing Tribal restoration priorities | R. E. Petrakis, L. M. Norman, B. R. Middleton | 2023 | Petrakis, R.E., Norman, L.M., and Middleton, B.R., 2023, Riparian vegetation response amid variable climate conditions across the Upper Gila River watershed—Informing Tribal restoration priorities: Frontiers in Environmental Science, v. 11, article 1179328, at https://doi.org/10.3389/fenvs.2023.1179328. |
Vegetative response to water availability on the San Carlos Apache Reservation | R. Petrakis, Z. Wu, J. McVay, B. Middleton, D. Dye, J. Vogel | 2016 | Petrakis, R., Wu, Z., McVay, J., Middleton, B., Dye, D., and Vogel, J., 2016, Vegetative response to water availability on the San Carlos Apache Reservation: Forest Ecology and Management, v. 378, p. 14–23, at https://doi.org/10.1016/j.foreco.2016.07.012. |
Trends in fire danger and population exposure along the wildland-urban interface | G. C. L. Peterson, S. E. Prince, A. G. Rappold | 2021 | Peterson, G.C.L., Prince, S.E., and Rappold, A.G., 2021, Trends in fire danger and population exposure along the wildland-urban interface: Environmental Science & Technology, v. 55, no. 23, p. 16257–16265, at https://doi.org/10.1021/acs.est.1c03835. |
Predicting streamflow duration from crowd-sourced flow observations | D. A. Peterson, S. K. Kampf, K. C. Puntenney-Desmond, M. P. Fairchild, S. Zipper, J. C. Hammond, M. R. V. Ross, M. G. Sears | 2024 | Peterson, D.A., Kampf, S.K., Puntenney-Desmond, K.C., Fairchild, M.P., Zipper, S., Hammond, J.C., Ross, M.R.V., and Sears, M.G., 2024, Predicting streamflow duration from crowd-sourced flow observations: Water Resources Research, v. 60, no. 1, article e2023WR035093, at https://doi.org/10.1029/2023WR035093. |
Effects of gradient, distance, curvature and aspect on steep burned and unburned hillslope soil erosion and deposition | L. M. Perreault, E. M. Yager, R. Aalto | 2017 | Perreault, L.M., Yager, E.M., and Aalto, R., 2017, Effects of gradient, distance, curvature and aspect on steep burned and unburned hillslope soil erosion and deposition: Earth Surface Processes and Landforms, v. 42, no. 7, p. 1033–1048, at https://doi.org/10.1002/esp.4067. |
Application of 210Pbex inventories to measure net hillslope erosion at burned sites | L. M. Perreault, E. M. Yager, R. Aalto | 2013 | Perreault, L.M., Yager, E.M., and Aalto, R., 2013, Application of 210Pbex inventories to measure net hillslope erosion at burned sites: Earth Surface Processes and Landforms, v. 38, no. 2, p. 133–145, at https://doi.org/10.1002/esp.3266. |
Multi-stage soil-hydraulic recovery and limited ravel accumulations following the 2017 Nuns and Tubbs wildfires in northern California | J. P. Perkins, D. Carlos, C. Skye, C.-D. Corina, J. Stock, J. P. Prancevic, M. Elisabeth, J. Jay | 2022 | Perkins, J.P., Carlos, D., Skye, C., Corina, C.-D., Stock, J., Prancevic, J.P., Elisabeth, M., and Jay, J., 2022, Multi-stage soil-hydraulic recovery and limited ravel accumulations following the 2017 Nuns and Tubbs wildfires in northern California: Journal of Geophysical Research—Earth Surface, v. 127, no. 6, article e2022JF006591, at https://doi.org/10.1029/2022JF006591. |
Wildfires can increase regulated nitrate, arsenic, and disinfection byproduct violations and concentrations in public drinking water supplies | M. J. Pennino, S. G. Leibowitz, J. E. Compton, M. Beyene, S. D. LeDuc | 2022 | Pennino, M.J., Leibowitz, S.G., Compton, J.E., Beyene, M., and LeDuc, S.D., 2022, Wildfires can increase regulated nitrate, arsenic, and disinfection byproduct violations and concentrations in public drinking water supplies: Science of the Total Environment, v. 804, article 149890, at https://doi.org/10.1016/j.scitotenv.2021.149890. |
Density-dependent plant growth drives grazer stimulation of aboveground net primary production in Yellowstone grasslands | J. F. Penner, D. A. Frank | 2021 | Penner, J.F., and Frank, D.A., 2021, Density-dependent plant growth drives grazer stimulation of aboveground net primary production in Yellowstone grasslands: Oecologia, v. 196, no. 3, p. 851–861, at https://doi.org/10.1007/s00442-021-04960-5. |
Changes in climate and land cover affect seasonal streamflow forecasts in the Rio Grande headwaters | C. A. Penn, D. W. Clow, G. A. Sexstone, S. F. Murphy | 2020 | Penn, C.A., Clow, D.W., Sexstone, G.A., and Murphy, S.F., 2020, Changes in climate and land cover affect seasonal streamflow forecasts in the Rio Grande headwaters: Journal of the American Water Resources Association, v. 56, no. 5, p. 882–902, at https://doi.org/10.1111/1752-1688.12863. |
Quality control and assessment of interpreter consistency of annual land cover reference data in an operational national monitoring program | B. W. Pengra, S. V. Stehman, J. A. Horton, D. J. Dockter, T. A. Schroeder, Z. Yang, W. B. Cohen, S. P. Healey, T. R. Loveland | 2020 | Pengra, B.W., Stehman, S.V., Horton, J.A., Dockter, D.J., Schroeder, T.A., Yang, Z., Cohen, W.B., Healey, S.P., and Loveland, T.R., 2020, Quality control and assessment of interpreter consistency of annual land cover reference data in an operational national monitoring program: Remote Sensing of Environment, v. 238, article 111261, at https://doi.org/10.1016/j.rse.2019.111261. |
Using Landsat imagery to assess burn severity of national forest inventory plots | F. Pelletier, B. N. I. Eskelson, V. J. Monleon, Y. C. Tseng | 2021 | Pelletier, F., Eskelson, B.N.I., Monleon, V.J., and Tseng, Y.C., 2021, Using Landsat imagery to assess burn severity of national forest inventory plots: Remote Sensing, v. 13, no. 10, article 1935, at https://doi.org/10.3390/rs13101935. |
Exploring invasibility with species distribution modeling—How does fire promote cheatgrass (Bromus tectorum) invasion within lower montane forests? | J. L. Peeler, E. A. H. Smithwick | 2018 | Peeler, J.L., and Smithwick, E.A.H., 2018, Exploring invasibility with species distribution modeling—How does fire promote cheatgrass (Bromus tectorum) invasion within lower montane forests?: Diversity and Distributions, v. 24, no. 9, p. 1308–1320, at https://doi.org/10.1111/ddi.12765. |
Wildfires identification—Semantic segmentation using support vector machine classifier | Pecha, Marek, Langford, Zachary, Horák, David, Tran Mills, Richard | 2022 | Pecha, M., Langford, Z., Horák, D., and Tran Mills, R., 2022, Wildfires identification—Semantic segmentation using support vector machine classifier, in Programs and Algorithms of Numerical Mathematics, PANM 21, Janov nad Nisou, Czech Republic, 19–24 June 2022, Proceedings of Seminar: Prague, Czech Republic, Institute of Mathematics CAS, p. 173–186, at https://doi.org/10.21136/panm.2022.16. |
Spatial dynamics of tree group and gap structure in an old-growth ponderosa pine-California black oak forest burned by repeated wildfires | N. C. Pawlikowski, M. Coppoletta, E. Knapp, A. H. Taylor | 2019 | Pawlikowski, N.C., Coppoletta, M., Knapp, E., and Taylor, A.H., 2019, Spatial dynamics of tree group and gap structure in an old-growth ponderosa pine-California black oak forest burned by repeated wildfires: Forest Ecology and Management, v. 434, p. 289–302, at https://doi.org/10.1016/j.foreco.2018.12.016. |
Understanding the effect of large wildfires on residents' well-being—What factors influence wildfire impact? | T. B. Paveglio, C. Kooistra, T. Hall, M. Pickering | 2016 | Paveglio, T.B., Kooistra, C., Hall, T., and Pickering, M., 2016, Understanding the effect of large wildfires on residents' well-being—What factors influence wildfire impact?: Forest Science, v. 62, no. 1, p. 59–69, at https://doi.org/10.5849/forsci.15-021. |
Persistent composition legacy and rapid structural change following successive fires in Sierra Nevada mixed conifer forests | A. Paudel, M. Coppoletta, K. Merriam, S. H. Markwith | 2022 | Paudel, A., Coppoletta, M., Merriam, K., and Markwith, S.H., 2022, Persistent composition legacy and rapid structural change following successive fires in Sierra Nevada mixed conifer forests: Forest Ecology and Management, v. 509, article 120079, at https://doi.org/10.1016/j.foreco.2022.120079. |
Determination of optimal set of spatio-temporal features for predicting burn probability in the state of California, USA | Pastorino, Javier, Director, Joseph W., Biswas, Ashis Kumer, Hawbaker, Todd J. | 2022 | Pastorino, J., Director, J.W., Biswas, A.K., and Hawbaker, T.J., 2022, Determination of optimal set of spatio-temporal features for predicting burn probability in the state of California, USA, in ACM Southeast Conference, Virtual Event, 19–20 April 2022, Proceedings: New York, N.Y., Association for Computing Machinery, p. 151–158, at https://doi.org/10.1145/3476883.3520228. |
Rapid monitoring of the abundance and spread of exotic annual grasses in the western United States using remote sensing and machine learning | N. J. Pastick, B. K. Wylie, M. B. Rigge, D. Dahal, S. P. Boyte, M. O. Jones, B. W. Allred, S. Parajuli, Z. Wu | 2021 | Pastick, N.J., Wylie, B.K., Rigge, M.B., Dahal, D., Boyte, S.P., Jones, M.O., Allred, B.W., Parajuli, S., and Wu, Z., 2021, Rapid monitoring of the abundance and spread of exotic annual grasses in the western United States using remote sensing and machine learning: AGU Advances, v. 2, no. 2, article e2020AV000298, at https://doi.org/10.1029/2020av000298. |
Spatial variability and landscape controls of near-surface permafrost within the Alaskan Yukon River Basin | N. J. Pastick, M. T. Jorgenson, B. K. Wylie, J. R. Rose, M. Rigge, M. A. Walvoord | 2014 | Pastick, N.J., Jorgenson, M.T., Wylie, B.K., Rose, J.R., Rigge, M., and Walvoord, M.A., 2014, Spatial variability and landscape controls of near-surface permafrost within the Alaskan Yukon River Basin: Journal of Geophysical Research—Biogeosciences, v. 119, no. 6, article 2013JG002594, at https://doi.org/10.1002/2013JG002594. |
Extending airborne electromagnetic surveys for regional active layer and permafrost mapping with remote sensing and ancillary data, Yukon Flats ecoregion, central Alaska | N. J. Pastick, M. T. Jorgenson, B. K. Wylie, B. J. Minsley, L. Ji, M. A. Walvoord, B. D. Smith, J. D. Abraham, J. R. Rose | 2013 | Pastick, N.J., Jorgenson, M.T., Wylie, B.K., Minsley, B.J., Ji, L., Walvoord, M.A., Smith, B.D., Abraham, J.D., and Rose, J.R., 2013, Extending airborne electromagnetic surveys for regional active layer and permafrost mapping with remote sensing and ancillary data, Yukon Flats ecoregion, central Alaska: Permafrost and Periglacial Processes, v. 24, no. 3, p. 184–199, at https://doi.org/10.1002/ppp.1775. |
Spatiotemporal remote sensing of ecosystem change and causation across Alaska | N. J. Pastick, M. T. Jorgenson, S. J. Goetz, B. M. Jones, B. K. Wylie, B. J. Minsley, H. Genet, J. F. Knight, D. K. Swanson, J. C. Jorgenson | 2019 | Pastick, N.J., Jorgenson, M.T., Goetz, S.J., Jones, B.M., Wylie, B.K., Minsley, B.J., Genet, H., Knight, J.F., Swanson, D.K., and Jorgenson, J.C., 2019, Spatiotemporal remote sensing of ecosystem change and causation across Alaska: Global Change Biology, v. 25, no. 3, p. 1171–1189, at https://doi.org/10.1111/gcb.14279. |
Recovery of western black-legged tick and vertebrate populations after a destructive wildfire in an intensively-studied woodland in northern California | E. L. Pascoe, C. E. Vaughn, M. I. Jones, R. H. Barrett, J. E. Foley, R. S. Lane | 2023 | Pascoe, E.L., Vaughn, C.E., Jones, M.I., Barrett, R.H., Foley, J.E., and Lane, R.S., 2023, Recovery of western black-legged tick and vertebrate populations after a destructive wildfire in an intensively-studied woodland in northern California: Journal of Vector Ecology, v. 48, no. 1, p. 19–36, at https://doi.org/10.52707/1081-1710-48.1.19. |
Benefits of the fire mitigation ecosystem service in The Great Dismal Swamp National Wildlife Refuge, Virginia, USA | B. Parthum, E. Pindilli, D. Hogan | 2017 | Parthum, B., Pindilli, E., and Hogan, D., 2017, Benefits of the fire mitigation ecosystem service in The Great Dismal Swamp National Wildlife Refuge, Virginia, USA: Journal of Environmental Management, v. 203, p. 375–382, at https://doi.org/10.1016/j.jenvman.2017.08.018. |
Land transitions from multivariate time series—Using seasonal trend analysis and segmentation to detect land-cover changes | B. Parmentier, J. R. Eastman | 2014 | Parmentier, B., and Eastman, J.R., 2014, Land transitions from multivariate time series—Using seasonal trend analysis and segmentation to detect land-cover changes: International Journal of Remote Sensing, v. 35, no. 2, p. 671–692, at https://doi.org/10.1080/01431161.2013.871595. |
Characterization of land transitions patterns from multivariate time series using seasonal trend analysis and principal component analysis | B. Parmentier | 2014 | Parmentier, B., 2014, Characterization of land transitions patterns from multivariate time series using seasonal trend analysis and principal component analysis: Remote Sensing, v. 6, no. 12, p. 12639–12665, at https://doi.org/10.3390/rs61212639. |
Fine-scale spatial climate variation and drought mediate the likelihood of reburning | S. A. Parks, M. A. Parisien, C. Miller, L. M. Holsinger, L. S. Baggett | 2018 | Parks, S.A., Parisien, M.A., Miller, C., Holsinger, L.M., and Baggett, L.S., 2018, Fine-scale spatial climate variation and drought mediate the likelihood of reburning: Ecological Applications, v. 28, no. 2, p. 573–586, at https://doi.org/10.1002/eap.1671. |
Fire activity and severity in the western US vary along proxy gradients representing fuel amount and fuel moisture | S. A. Parks, M. A. Parisien, C. Miller, S. Z. Dobrowski | 2014 | Parks, S.A., Parisien, M.A., Miller, C., and Dobrowski, S.Z., 2014, Fire activity and severity in the western US vary along proxy gradients representing fuel amount and fuel moisture: PLoS ONE, v. 9, no. 6, article e99699, at https://doi.org/10.1371/journal.pone.0099699. |
Wildland fire deficit and surplus in the western United States, 1984–2012 | S. A. Parks, C. Miller, M.-A. Parisien, L. M. Holsinger, S. Z. Dobrowski, J. Abatzoglou | 2015 | Parks, S.A., Miller, C., Parisien, M.-A., Holsinger, L.M., Dobrowski, S.Z., and Abatzoglou, J., 2015, Wildland fire deficit and surplus in the western United States, 1984–2012: Ecosphere, v. 6, no. 12, article 275, at https://doi.org/10.1890/es15-00294.1. |
Previous fires moderate burn severity of subsequent wildland fires in two large western US wilderness areas | S. A. Parks, C. Miller, C. R. Nelson, Z. A. Holden | 2014 | Parks, S.A., Miller, C., Nelson, C.R., and Holden, Z.A., 2014, Previous fires moderate burn severity of subsequent wildland fires in two large western US wilderness areas: Ecosystems, v. 17, no. 1, p. 29–42, at https://doi.org/10.1007/s10021-013-9704-x. |
How will climate change affect wildland fire severity in the western US? | S. A. Parks, C. Miller, J. T. Abatzoglou, L. M. Holsinger, M.-A. Parisien, S. Z. Dobrowski | 2016 | Parks, S.A., Miller, C., Abatzoglou, J.T., Holsinger, L.M., Parisien, M.-A., and Dobrowski, S.Z., 2016, How will climate change affect wildland fire severity in the western US?: Environmental Research Letters, v. 11, no. 3, article 035002, at https://doi.org/10.1088/1748-9326/11/3/035002. |
Mean composite fire severity metrics computed with google earth engine offer improved accuracy and expanded mapping potential | S. A. Parks, L. M. Holsinger, M. A. Voss, R. A. Loehman, N. P. Robinson | 2018 | Parks, S.A., Holsinger, L.M., Voss, M.A., Loehman, R.A., and Robinson, N.P., 2018, Mean composite fire severity metrics computed with google earth engine offer improved accuracy and expanded mapping potential: Remote Sensing, v. 10, no. 6, article 879, at https://doi.org/10.3390/rs10060879. |
High-severity fire—Evaluating its key drivers and mapping its probability across western US forests | S. A. Parks, L. M. Holsinger, M. H. Panunto, W. M. Jolly, S. Z. Dobrowski, G. K. Dillon | 2018 | Parks, S.A., Holsinger, L.M., Panunto, M.H., Jolly, W.M., Dobrowski, S.Z., and Dillon, G.K., 2018, High-severity fire—Evaluating its key drivers and mapping its probability across western US forests: Environmental Research Letters, v. 13, no. 4, article 044037, at https://doi.org/10.1088/1748-9326/aab791. |
Wildland fire as a self-regulating mechanism—The role of previous burns and weather in limiting fire progression | S. A. Parks, L. M. Holsinger, C. Miller, C. R. Nelson | 2015 | Parks, S.A., Holsinger, L.M., Miller, C., and Nelson, C.R., 2015, Wildland fire as a self-regulating mechanism—The role of previous burns and weather in limiting fire progression: Ecological Applications, v. 25, no. 6, p. 1478–1492, at https://doi.org/10.1890/14-1430.1.sm. |
Contemporary wildfires are more severe compared to the historical reference period in western US dry conifer forests | S. A. Parks, L. M. Holsinger, K. Blankenship, G. K. Dillon, S. A. Goeking, R. Swaty | 2023 | Parks, S.A., Holsinger, L.M., Blankenship, K., Dillon, G.K., Goeking, S.A., and Swaty, R., 2023, Contemporary wildfires are more severe compared to the historical reference period in western US dry conifer forests: Forest Ecology and Management, v. 544, article 121232, at https://doi.org/10.1016/j.foreco.2023.121232. |
Quantifying the risk of fire-facilitated transition to non-forest in California and the Southwest, Final Report | Parks, S.A., Dobrowski, S.Z., Shaw, J.D., Miller, C. | 2019 | Parks, S.A., Dobrowski, S.Z., Shaw, J.D., and Miller, C., 2019, Quantifying the risk of fire-facilitated transition to non-forest in California and the Southwest, Final Report: Joint Fire Science Program JFSP PROJECT ID—15-1-03-20, 37 p., at https://www.frames.gov/catalog/57635. |
What drives low-severity fire in the southwestern USA? | S. A. Parks, S. Z. Dobrowski, M. H. Panunto | 2018 | Parks, S.A., Dobrowski, S.Z., and Panunto, M.H., 2018, What drives low-severity fire in the southwestern USA?: Forests, v. 9, no. 4, article 165, at https://doi.org/10.3390/f9040165. |
A new metric for quantifying burn severity—The relativized burn ratio | S. A. Parks, G. K. Dillon, C. Miller | 2014 | Parks, S.A., Dillon, G.K., and Miller, C., 2014, A new metric for quantifying burn severity—The relativized burn ratio: Remote Sensing, v. 6, no. 3, p. 1827–1844, at https://doi.org/10.3390/rs6031827. |
Warmer and drier fire seasons contribute to increases in area burned at high severity in western US forests from 1985 to 2017 | S. A. Parks, J. T. Abatzoglou | 2020 | Parks, S.A., and Abatzoglou, J.T., 2020, Warmer and drier fire seasons contribute to increases in area burned at high severity in western US forests from 1985 to 2017: Geophysical Research Letters, v. 47, no. 22, article e2020GL089858, at https://doi.org/10.1029/2020GL089858. |
Demographic effects of a megafire on a declining prairie grouse in the mixed-grass prairie | N. J. Parker, D. S. Sullins, D. A. Haukos, K. A. Fricke, C. A. Hagen, A. A. Ahlers | 2022 | Parker, N.J., Sullins, D.S., Haukos, D.A., Fricke, K.A., Hagen, C.A., and Ahlers, A.A., 2022, Demographic effects of a megafire on a declining prairie grouse in the mixed-grass prairie: Ecology and Evolution, v. 12, no. 12, article e9544, at https://doi.org/10.1002/ece3.9544. |
Recovery of working grasslands following a megafire in the southern mixed-grass prairie | N. J. Parker, D. S. Sullins, D. A. Haukos, K. A. Fricke, C. A. Hagen | 2022 | Parker, N.J., Sullins, D.S., Haukos, D.A., Fricke, K.A., and Hagen, C.A., 2022, Recovery of working grasslands following a megafire in the southern mixed-grass prairie: Global Ecology and Conservation, v. 36, article e02142, at https://doi.org/10.1016/j.gecco.2022.e02142. |
Characterizing spatial burn severity patterns of 2016 Chimney Tops 2 fire using multi-temporal Landsat and NEON LiDAR data | T. Park, S. Sim | 2023 | Park, T., and Sim, S., 2023, Characterizing spatial burn severity patterns of 2016 Chimney Tops 2 fire using multi-temporal Landsat and NEON LiDAR data: Frontiers in Remote Sensing, v. 4, article 1096000, at https://doi.org/10.3389/frsen.2023.1096000. |
Spatial variability in wildfire probability across the western United States | M. A. Parisien, S. Snetsinger, J. A. Greenberg, C. R. Nelson, T. Schoennagel, S. Z. Dobrowski, M. A. Moritz | 2012 | Parisien, M.A., Snetsinger, S., Greenberg, J.A., Nelson, C.R., Schoennagel, T., Dobrowski, S.Z., and Moritz, M.A., 2012, Spatial variability in wildfire probability across the western United States: International Journal of Wildland Fire, v. 21, no. 4, p. 313–327, at https://doi.org/10.1071/WF11044. |
The spatially varying influence of humans on fire probability in North America | M. A. Parisien, C. Miller, S. A. Parks, E. R. Delancey, F. N. Robinne, M. D. Flannigan | 2016 | Parisien, M.A., Miller, C., Parks, S.A., Delancey, E.R., Robinne, F.N., and Flannigan, M.D., 2016, The spatially varying influence of humans on fire probability in North America: Environmental Research Letters, v. 11, no. 7, article 075005, at https://doi.org/10.1088/1748-9326/11/7/075005. |
Abrupt, climate-induced increase in wildfires in British Columbia since the mid-2000s | M. A. Parisien, Q. E. Barber, M. L. Bourbonnais, L. D. Daniels, M. D. Flannigan, R. W. Gray, K. M. Hoffman, P. Jain, S. L. Stephens, S. W. Taylor, E. Whitman | 2023 | Parisien, M.A., Barber, Q.E., Bourbonnais, M.L., Daniels, L.D., Flannigan, M.D., Gray, R.W., Hoffman, K.M., Jain, P., Stephens, S.L., et al., 2023, Abrupt, climate-induced increase in wildfires in British Columbia since the mid-2000s: Communications Earth & Environment, v. 4, no. 1, article 309, at https://doi.org/10.1038/s43247-023-00977-1. |
Commentary on the article Burn probability simulation and subsequent wildland fire activity in Alberta, Canada - Implications for risk assessment and strategic planning by JL Beverly and N. McLoughlin | M. A. Parisien, A. A. Ager, A. M. Barros, D. Dawe, S. Erni, M. A. Finney, C. W. McHugh, C. Miller, S. A. Parks, K. L. Riley, K. C. Short, C. A. Stockdale, X. L. Wang, E. Whitman | 2020 | Parisien, M.A., Ager, A.A., Barros, A.M., Dawe, D., Erni, S., Finney, M.A., McHugh, C.W., Miller, C., Parks, S.A., et al., 2020, Commentary on the article Burn probability simulation and subsequent wildland fire activity in Alberta, Canada - Implications for risk assessment and strategic planning by JL Beverly and N. McLoughlin: Forest Ecology and Management, v. 460, article 117698, at https://doi.org/10.1016/j.foreco.2019.117698. |
Climate-altered fire regimes may increase extirpation risk in an upper subalpine conifer species of management concern | E. R. Pansing, D. F. Tomback, M. B. Wunder | 2020 | Pansing, E.R., Tomback, D.F., and Wunder, M.B., 2020, Climate-altered fire regimes may increase extirpation risk in an upper subalpine conifer species of management concern: Ecosphere, v. 11, no. 8, article e03220, at https://doi.org/10.1002/ecs2.3220. |
Differing sensitivities to fire disturbance result in large differences among remotely sensed products of vegetation disturbance | J. Palomino, M. Kelly | 2019 | Palomino, J., and Kelly, M., 2019, Differing sensitivities to fire disturbance result in large differences among remotely sensed products of vegetation disturbance: Ecosystems, v. 22, no. 8, p. 1767–1786, at https://doi.org/10.1007/s10021-019-00367-9. |
Turning up the heat—Long?term water quality responses to wildfires and climate change in a hypereutrophic lake | A. De Palma?Dow, I. M. McCullough, J. A. Brentrup | 2022 | De Palma?Dow, A., McCullough, I.M., and Brentrup, J.A., 2022, Turning up the heat—Long?term water quality responses to wildfires and climate change in a hypereutrophic lake: Ecosphere, v. 13, no. 12, article e4271, at https://doi.org/10.1002/ecs2.4271. |
Locating forest management units using remote sensing and geostatistical tools in north-central Washington, USA | P. Palaiologou, M. Essen, J. Hogland, K. Kalabokidis | 2020 | Palaiologou, P., Essen, M., Hogland, J., and Kalabokidis, K., 2020, Locating forest management units using remote sensing and geostatistical tools in north-central Washington, USA: Sensors, v. 20, no. 9, article 2454, at https://doi.org/10.3390/s20092454. |
A classification of US wildland firefighter entrapments based on coincident fuels, weather, and topography | W. G. Page, P. H. Freeborn, B. W. Butler, W. M. Jolly | 2019 | Page, W.G., Freeborn, P.H., Butler, B.W., and Jolly, W.M., 2019, A classification of US wildland firefighter entrapments based on coincident fuels, weather, and topography: Fire, v. 2, no. 4, article 52, at https://doi.org/10.3390/fire2040052. |
Spatial patterns of ponderosa pine regeneration in high-severity burn patches | S. M. Owen, C. H. Sieg, A. J. Sánchez Meador, P. Z. Fulé, J. M. Iniguez, L. S. Baggett, P. J. Fornwalt, M. A. Battaglia | 2017 | Owen, S.M., Sieg, C.H., Sánchez Meador, A.J., Fulé, P.Z., Iniguez, J.M., Baggett, L.S., Fornwalt, P.J., and Battaglia, M.A., 2017, Spatial patterns of ponderosa pine regeneration in high-severity burn patches: Forest Ecology and Management, v. 405, p. 134–149, at https://doi.org/10.1016/j.foreco.2017.09.005. |
Persistent effects of fire severity on ponderosa pine regeneration niches and seedling growth | S. M. Owen, C. H. Sieg, P. Z. Fulé, C. A. Gehring, L. Baggett, J. M. Iniguez, P. J. Fornwalt, M. A. Battaglia | 2020 | Owen, S.M., Sieg, C.H., Fulé, P.Z., Gehring, C.A., Baggett, L., Iniguez, J.M., Fornwalt, P.J., and Battaglia, M.A., 2020, Persistent effects of fire severity on ponderosa pine regeneration niches and seedling growth: Forest Ecology and Management, v. 477, article 118502, at https://doi.org/10.1016/j.foreco.2020.118502. |
Large, high-severity burn patches limit fungal recovery 13 years after wildfire in a ponderosa pine forest | S. M. Owen, A. M. Patterson, C. A. Gehring, C. H. Sieg, L. S. Baggett, P. Z. Fulé | 2019 | Owen, S.M., Patterson, A.M., Gehring, C.A., Sieg, C.H., Baggett, L.S., and Fulé, P.Z., 2019, Large, high-severity burn patches limit fungal recovery 13 years after wildfire in a ponderosa pine forest: Soil Biology and Biochemistry, v. 139, article 107616, at https://doi.org/10.1016/j.soilbio.2019.107616. |
Post-fire ponderosa pine regeneration with and without planting in Arizona and New Mexico | J. Ouzts, T. Kolb, D. Huffman, A. S. Meador | 2015 | Ouzts, J., Kolb, T., Huffman, D., and Meador, A.S., 2015, Post-fire ponderosa pine regeneration with and without planting in Arizona and New Mexico: Forest Ecology and Management, v. 354, p. 281–290, at https://doi.org/10.1016/j.foreco.2015.06.001. |
Effects of compound disturbance on Canada lynx and snowshoe hare—Wildfire and forest management influence timing and intensity of use | L. E. Olson, J. S. Crotteau, S. Fox, G. Hanvey, J. D. Holbrook, S. Jackson, J. R. Squires | 2023 | Olson, L.E., Crotteau, J.S., Fox, S., Hanvey, G., Holbrook, J.D., Jackson, S., and Squires, J.R., 2023, Effects of compound disturbance on Canada lynx and snowshoe hare—Wildfire and forest management influence timing and intensity of use: Forest Ecology and Management, v. 530, article 120757, at https://doi.org/10.1016/j.foreco.2022.120757. |
N/A | Oetgen, J., Dube, A., Chamberlain, M.J., Engeling, A., Skow, K.L., Collier, B.A. | 2016 | Oetgen, J., Dube, A., Chamberlain, M.J., Engeling, A., Skow, K.L., and Collier, B.A., 2016, Evaluating Rio Grande wild turkey movements post catastrophic wildfire using 2 selection analysis approaches, in 11th National Wild Turkey Symposium, Tucson, Ariz., 5–7 January 2016, Proceedings: Edgefield, S.C., National Wild Turkey Federation, p. 127–141. |
Projected climate-fire interactions drive forest to shrubland transition on an Arizona Sky Island | C. D. O’Connor, D. A. Falk, G. M. Garfin | 2020 | O’Connor, C.D., Falk, D.A., and Garfin, G.M., 2020, Projected climate-fire interactions drive forest to shrubland transition on an Arizona Sky Island: Frontiers in Environmental Science, v. 8, article 137, at https://doi.org/10.3389/fenvs.2020.00137. |
Getting ahead of the wildfire problem—Quantifying and mapping management challenges and opportunities | C. O’Connor, M. Thompson, F. Rodríguez y Silva | 2016 | O’Connor, C., Thompson, M., and Rodríguez y Silva, F., 2016, Getting ahead of the wildfire problem—Quantifying and mapping management challenges and opportunities: Geosciences, v. 6, no. 3, article 35, at https://doi.org/10.3390/geosciences6030035. |
Post-fire forest dynamics and climate variability affect spatial and temporal properties of spruce beetle outbreaks on a Sky Island mountain range | C. D. O'Connor, A. M. Lynch, D. A. Falk, T. W. Swetnam | 2015 | O'Connor, C.D., Lynch, A.M., Falk, D.A., and Swetnam, T.W., 2015, Post-fire forest dynamics and climate variability affect spatial and temporal properties of spruce beetle outbreaks on a Sky Island mountain range: Forest Ecology and Management, v. 336, p. 148–162, at https://doi.org/10.1016/j.foreco.2014.10.021. |
Fire severity, size, and climate associations diverge from historical precedent along an ecological gradient in the Pinaleño Mountains, Arizona, USA | C. D. O'Connor, D. A. Falk, A. M. Lynch, T. W. Swetnam | 2014 | O'Connor, C.D., Falk, D.A., Lynch, A.M., and Swetnam, T.W., 2014, Fire severity, size, and climate associations diverge from historical precedent along an ecological gradient in the Pinaleño Mountains, Arizona, USA: Forest Ecology and Management, v. 329, p. 264–278, at https://doi.org/10.1016/j.foreco.2014.06.032. |
An empirical machine learning method for predicting potential fire control locations for pre-fire planning and operational fire management | C. D. O'Connor, D. E. Calkin, M. P. Thompson | 2017 | O'Connor, C.D., Calkin, D.E., and Thompson, M.P., 2017, An empirical machine learning method for predicting potential fire control locations for pre-fire planning and operational fire management: International Journal of Wildland Fire, v. 26, no. 7, p. 587–597, at https://doi.org/10.1071/wf16135. |
Using social media data and machine learning to map recreational ecosystem services | C. Nyelele, C. Keske, M. G. Chung, H. Guo, B. N. Egoh | 2023 | Nyelele, C., Keske, C., Chung, M.G., Guo, H., and Egoh, B.N., 2023, Using social media data and machine learning to map recreational ecosystem services: Ecological Indicators, v. 154, article 110606, at https://doi.org/10.1016/j.ecolind.2023.110606. |
A new picture of fire extent, variability, and drought interaction in prescribed fire landscapes—Insights from Florida government records | H. K. Nowell, C. D. Holmes, K. Robertson, C. Teske, J. K. Hiers | 2018 | Nowell, H.K., Holmes, C.D., Robertson, K., Teske, C., and Hiers, J.K., 2018, A new picture of fire extent, variability, and drought interaction in prescribed fire landscapes—Insights from Florida government records: Geophysical Research Letters, v. 45, no. 15, p. 7874–7884, at https://doi.org/10.1029/2018GL078679. |
The impacts of rising vapour pressure deficit in natural and managed ecosystems | K. A. Novick, D. L. Ficklin, C. Grossiord, A. G. Konings, J. Martinez-Vilalta, W. Sadok, A. T. Trugman, A. P. Williams, A. J. Wright, J. T. Abatzoglou, M. P. Dannenberg, P. Gentine, K. Guan, M. R. Johnston, L. E. L. Lowman, D. J. P. Moore, N. G. McDowell | in press | Novick, K.A., Ficklin, D.L., Grossiord, C., Konings, A.G., Martinez-Vilalta, J., Sadok, W., Trugman, A.T., Williams, A.P., Wright, A.J., et al., in press, The impacts of rising vapour pressure deficit in natural and managed ecosystems: Plant, Cell & Environment, at https://doi.org/10.1111/pce.14846. |
Pyrosilviculture needed for landscape resilience of dry Western United States forests | M. P. North, R. A. York, B. M. Collins, M. D. Hurteau, G. M. Jones, E. E. Knapp, L. Kobziar, H. McCann, M. D. Meyer, S. L. Stephens, R. E. Tompkins, C. L. Tubbesing | 2021 | North, M.P., York, R.A., Collins, B.M., Hurteau, M.D., Jones, G.M., Knapp, E.E., Kobziar, L., McCann, H., Meyer, M.D., et al., 2021, Pyrosilviculture needed for landscape resilience of dry Western United States forests: Journal of Forestry, v. 119, no. 5, p. 520–544, at https://doi.org/10.1093/jofore/fvab026. |
Review of broad-scale drought monitoring of forests—Toward an integrated data mining approach | S. P. Norman, F. H. Koch, W. W. Hargrove | 2016 | Norman, S.P., Koch, F.H., and Hargrove, W.W., 2016, Review of broad-scale drought monitoring of forests—Toward an integrated data mining approach: Forest Ecology and Management, v. 380, p. 346–358, at https://doi.org/10.1016/j.foreco.2016.06.027. |
Wildfire catalyzes upward range expansion of trembling aspen in southern Rocky Mountain beetle-killed forests | K. M. Nigro, M. E. Rocca, M. A. Battaglia, J. D. Coop, M. D. Redmond | 2022 | Nigro, K.M., Rocca, M.E., Battaglia, M.A., Coop, J.D., and Redmond, M.D., 2022, Wildfire catalyzes upward range expansion of trembling aspen in southern Rocky Mountain beetle-killed forests: Journal of Biogeography, v. 49, no. 1, p. 201–214, at https://doi.org/10.1111/jbi.14302. |
Fire frequency impacts soil properties and processes in sagebrush steppe ecosystems of the Columbia Basin | L. Nichols, D. J. Shinneman, S. K. McIlroy, M.-A. de Graaff | 2021 | Nichols, L., Shinneman, D.J., McIlroy, S.K., and de Graaff, M.-A., 2021, Fire frequency impacts soil properties and processes in sagebrush steppe ecosystems of the Columbia Basin: Applied Soil Ecology, v. 165, article 103967, at https://doi.org/10.1016/j.apsoil.2021.103967. |
Topographic variation in tree group and gap structure in Sierra Nevada mixed-conifer forests with active fire regimes | J. Ng, M. P. North, A. J. Arditti, M. R. Cooper, J. A. Lutz | 2020 | Ng, J., North, M.P., Arditti, A.J., Cooper, M.R., and Lutz, J.A., 2020, Topographic variation in tree group and gap structure in Sierra Nevada mixed-conifer forests with active fire regimes: Forest Ecology and Management, v. 472, article 118220, at https://doi.org/10.1016/j.foreco.2020.118220. |
Prolonged drought in a northern California coastal region suppresses wildfire impacts on hydrology | M. E. Newcomer, J. Underwood, S. F. Murphy, C. Ulrich, T. Schram, S. R. Maples, J. Peña, E. R. Siirila?Woodburn, M. Trotta, J. Jasperse, D. Seymour, S. S. Hubbard | 2023 | Newcomer, M.E., Underwood, J., Murphy, S.F., Ulrich, C., Schram, T., Maples, S.R., Peña, J., Siirila?Woodburn, E.R., Trotta, M., et al., 2023, Prolonged drought in a northern California coastal region suppresses wildfire impacts on hydrology: Water Resources Research, v. 59, no. 8, article e2022WR034206, at https://doi.org/10.1029/2022wr034206. |
Influences of wildfire, habitat size, and connectivity on trout in headwater streams revealed by patterns of genetic diversity | H. Neville, J. Dunham, A. Rosenberger, J. Umek, B. Nelson | 2009 | Neville, H., Dunham, J., Rosenberger, A., Umek, J., and Nelson, B., 2009, Influences of wildfire, habitat size, and connectivity on trout in headwater streams revealed by patterns of genetic diversity: Transactions of the American Fisheries Society, v. 138, no. 6, p. 1314–1327, at https://doi.org/10.1577/T08-162.1. |
Do repeated wildfires promote restoration of oak woodlands in mixed-conifer landscapes? | D. G. Nemens, J. M. Varner, K. R. Kidd, B. Wing | 2018 | Nemens, D.G., Varner, J.M., Kidd, K.R., and Wing, B., 2018, Do repeated wildfires promote restoration of oak woodlands in mixed-conifer landscapes?: Forest Ecology and Management, v. 427, p. 143–151, at https://doi.org/10.1016/j.foreco.2018.05.023. |
Assessing spatiotemporal relationships between wildfire and mountain pine beetle disturbances across multiple time lags | M. F. Nelson, M. Ciochina, C. Bone | 2016 | Nelson, M.F., Ciochina, M., and Bone, C., 2016, Assessing spatiotemporal relationships between wildfire and mountain pine beetle disturbances across multiple time lags: Ecosphere, v. 7, no. 10, article e01482, at https://doi.org/10.1002/ecs2.1482. |
Landscape variation in tree regeneration and snag fall drive fuel loads in 24-year old post-fire lodgepole pine forests | K. N. Nelson, M. G. Turner, W. H. Romme, D. B. Tinker | 2016 | Nelson, K.N., Turner, M.G., Romme, W.H., and Tinker, D.B., 2016, Landscape variation in tree regeneration and snag fall drive fuel loads in 24-year old post-fire lodgepole pine forests: Ecological Applications, v. 26, no. 8, p. 2422–2436, at https://doi.org/10.1002/eap.1412. |
LANDFIRE 2010—Updates to the national dataset to support improved fire and natural resource management | Nelson, Kurtis J., Long, Donald G., Connot, Joel A. | 2016 | Nelson, K.J., Long, D.G., and Connot, J.A., 2016, LANDFIRE 2010—Updates to the national dataset to support improved fire and natural resource management: Reston, Va., U.S. Geological Survey Open-File Report 2016-1010, 59 p., at https://doi.org/10.3133/ofr20161010. |
The LANDFIRE refresh strategy—Updating the national dataset | K. J. Nelson, J. Connot, B. Peterson, C. Martin | 2013 | Nelson, K.J., Connot, J., Peterson, B., and Martin, C., 2013, The LANDFIRE refresh strategy—Updating the national dataset: Fire Ecology, v. 9, no. 2, p. 80–101, at https://doi.org/10.4996/fireecology.0902080. |
Evaluating an automated approach for monitoring forest disturbances in the Pacific Northwest from logging, fire and insect outbreaks with Landsat time series data | C. S. R. Neigh, D. K. Bolton, J. J. Williams, M. Diabate | 2014 | Neigh, C.S.R., Bolton, D.K., Williams, J.J., and Diabate, M., 2014, Evaluating an automated approach for monitoring forest disturbances in the Pacific Northwest from logging, fire and insect outbreaks with Landsat time series data: Forests, v. 5, no. 12, p. 3169–3198, at https://doi.org/10.3390/f5123169. |
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Grounded—An enterprise-wide look at Department of the Air Force installation exposure to natural hazards, Implications for infrastructure investment decisionmaking and continuity of operations planning | Narayanan, Anu, Lostumbo, Michael J., Van Abel, Kristin, Wilson, Michael T., Wirth, Anna Jean, Rahim, Ali | 2021 | Narayanan, A., Lostumbo, M.J., Van Abel, K., Wilson, M.T., Wirth, A.J., and Rahim, A., 2021, Grounded—An enterprise-wide look at Department of the Air Force installation exposure to natural hazards, Implications for infrastructure investment decisionmaking and continuity of operations planning: Santa Monica, Calif., Rand Corporation RR-A523-1, 146 p., at https://www.rand.org/pubs/research_reports/RRA523-1.html. |
A fuelscape for all-lands in Utah | Napoli, J., Gilbertson-Day, J.W., Scott, J.H. | 2022 | Napoli, J., Gilbertson-Day, J.W., and Scott, J.H., 2022, A fuelscape for all-lands in Utah: Utah Department of Natural Resources, Division of Forestry, Fire and State Lands, 23 p., at https://pyrologix.com/reports/Utah_FuelscapeReport.pdf. |
A synthesis of the effects of cheatgrass invasion on US Great Basin carbon storage | R. C. Nagy, E. J. Fusco, J. K. Balch, J. T. Finn, A. Mahood, J. M. Allen, B. A. Bradley | 2020 | Nagy, R.C., Fusco, E.J., Balch, J.K., Finn, J.T., Mahood, A., Allen, J.M., and Bradley, B.A., 2020, A synthesis of the effects of cheatgrass invasion on US Great Basin carbon storage: Journal of Applied Ecology, v. 58, no. 2, p. 327–337, at https://doi.org/10.1111/1365-2664.13770. |
Wilderness in the 21st century—A framework for testing assumptions about ecological intervention in wilderness using a case study of fire ecology in the Rocky Mountains | C. E. Naficy, E. G. Keeling, P. Landres, P. F. Hessburg, T. T. Veblen, A. Sala | 2016 | Naficy, C.E., Keeling, E.G., Landres, P., Hessburg, P.F., Veblen, T.T., and Sala, A., 2016, Wilderness in the 21st century—A framework for testing assumptions about ecological intervention in wilderness using a case study of fire ecology in the Rocky Mountains: Journal of Forestry, v. 114, no. 3, p. 384–395, at https://doi.org/10.5849/jof.15-010. |
Forest fire severity affects host plant quality and insect herbivore damage | S. M. Murphy, M. C. Vidal, T. P. Smith, C. J. Hallagan, E. D. Broder, D. Rowland, L. C. Cepero | 2018 | Murphy, S.M., Vidal, M.C., Smith, T.P., Hallagan, C.J., Broder, E.D., Rowland, D., and Cepero, L.C., 2018, Forest fire severity affects host plant quality and insect herbivore damage: Frontiers in Ecology and Evolution, v. 6, article 135, at https://doi.org/10.3389/fevo.2018.00135. |
Beyond the 1984 perspective—Narrow focus on modern wildfire trends underestimates future risks to water security | B. P. Murphy, L. L. Yocom, P. Belmont | 2018 | Murphy, B.P., Yocom, L.L., and Belmont, P., 2018, Beyond the 1984 perspective—Narrow focus on modern wildfire trends underestimates future risks to water security: Earth's Future, v. 6, no. 11, p. 1492–1497, at https://doi.org/10.1029/2018ef001006. |
Post-wildfire sediment cascades—A modeling framework linking debris flow generation and network-scale sediment routing | B. P. Murphy, J. A. Czuba, P. Belmont | 2019 | Murphy, B.P., Czuba, J.A., and Belmont, P., 2019, Post-wildfire sediment cascades—A modeling framework linking debris flow generation and network-scale sediment routing: Earth Surface Processes and Landforms, v. 44, no. 11, p. 2126–2140, at https://doi.org/10.1002/esp.4635. |
Define–Investigate–Estimate–Map (Diem) framework for modeling habitat threats | K. Muhammed, A. Anandhi, G. Chen, K. Poole | 2021 | Muhammed, K., Anandhi, A., Chen, G., and Poole, K., 2021, Define–Investigate–Estimate–Map (Diem) framework for modeling habitat threats: Sustainability, v. 13, no. 20, article 11259, at https://doi.org/10.3390/su132011259. |
Climate relationships with increasing wildfire in the southwestern US from 1984 to 2015 | S. E. Mueller, A. E. Thode, E. Q. Margolis, L. L. Yocom, J. D. Young, J. M. Iniguez | 2020 | Mueller, S.E., Thode, A.E., Margolis, E.Q., Yocom, L.L., Young, J.D., and Iniguez, J.M., 2020, Climate relationships with increasing wildfire in the southwestern US from 1984 to 2015: Forest Ecology and Management, v. 460, article 117861, at https://doi.org/10.1016/j.foreco.2019.117861. |
Satellite-based assessment of climate controls on US burned area | D. C. Morton, G. J. Collatz, D. Wang, J. T. Randerson, L. Giglio, Y. Chen | 2013 | Morton, D.C., Collatz, G.J., Wang, D., Randerson, J.T., Giglio, L., and Chen, Y., 2013, Satellite-based assessment of climate controls on US burned area: Biogeosciences, v. 10, no. 1, p. 247–260, at https://doi.org/10.5194/bg-10-247-2013. |
Post-wildfire salvage logging effects on snag structure and dead woody fuel loadings | C. J. Morris, M. C. Kennedy, S. C. Harrison, E. Alvarado, C. Desautel, J. Holford, S. Logue | 2023 | Morris, C.J., Kennedy, M.C., Harrison, S.C., Alvarado, E., Desautel, C., Holford, J., and Logue, S., 2023, Post-wildfire salvage logging effects on snag structure and dead woody fuel loadings: Canadian Journal of Forest Research, v. 53, no. 2, p. 103–118, at https://doi.org/10.1139/cjfr-2021-0089. |
Using a trait-based approach to asses fire resistance in forest landscapes of the Inland Northwest, USA | J. V. Moris, M. J. Reilly, Z. Yang, W. B. Cohen, R. Motta, D. Ascoli | 2022 | Moris, J.V., Reilly, M.J., Yang, Z., Cohen, W.B., Motta, R., and Ascoli, D., 2022, Using a trait-based approach to asses fire resistance in forest landscapes of the Inland Northwest, USA: Landscape Ecology, v. 37, p. 2149–2164, at https://doi.org/10.1007/s10980-022-01478-w. |
Mapping tree cover expansion in Montana, U.S.A. rangelands using high-resolution historical aerial imagery | S. L. Morford, B. W. Allred, E. R. Jensen, J. D. Maestas, K. R. Mueller, C. L. Pacholski, J. T. Smith, J. D. Tack, K. N. Tackett, D. E. Naugle | 2024 | Morford, S.L., Allred, B.W., Jensen, E.R., Maestas, J.D., Mueller, K.R., Pacholski, C.L., Smith, J.T., Tack, J.D., Tackett, K.N., and Naugle, D.E., 2024, Mapping tree cover expansion in Montana, U.S.A. rangelands using high-resolution historical aerial imagery: Remote Sensing in Ecology and Conservation, v. 10, no. 1, p. 91–105, at https://doi.org/10.1002/rse2.357. |
A comparison of burned area time series in the Alaskan boreal forests from different remote sensing products | R. Moreno, L. García, Arbelo | 2019 | Moreno, R., García, L., and Arbelo, 2019, A comparison of burned area time series in the Alaskan boreal forests from different remote sensing products: Forests, v. 10, no. 5, article 363, at https://doi.org/10.3390/f10050363. |
Mapping forest canopy fuels in the western United States with LiDAR-Landsat covariance | C. J. Moran, V. R. Kane, C. A. Seielstad | 2020 | Moran, C.J., Kane, V.R., and Seielstad, C.A., 2020, Mapping forest canopy fuels in the western United States with LiDAR-Landsat covariance: Remote Sensing, v. 12, no. 6, article 1000, at https://doi.org/10.3390/rs12061000. |
Creosote growth rate and reproduction increase in postfire environments | R. Lee Molinari, T. B. B. Bishop, M. F. Bekker, S. G. Kitchen, L. Allphin, S. B. St Clair | 2019 | Lee Molinari, R., Bishop, T.B.B., Bekker, M.F., Kitchen, S.G., Allphin, L., and St Clair, S.B., 2019, Creosote growth rate and reproduction increase in postfire environments: Ecology and Evolution, v. 9, no. 22, p. 12897–12905, at https://doi.org/10.1002/ece3.5771. |
Northwest Forest Plan—The first 15 years (1994–2008)—Status and trends of late-successional and old-growth forests | Moeur, M., Ohmann, J. L., Kennedy, R. E., Cohen, W. B., Gregory, M. J., Yang, Z., Roberts, H. M., Spies, T. A., Fiorella, M. | 2011 | Moeur, M., Ohmann, J.L., Kennedy, R.E., Cohen, W.B., Gregory, M.J., Yang, Z., Roberts, H.M., Spies, T.A., and Fiorella, M., 2011, Northwest Forest Plan—The first 15 years (1994–2008)—Status and trends of late-successional and old-growth forests: Portland, Oreg., U.S. Forest Service, Pacific Northwest Research Station Gen. Tech. Rep. PNW-GTR-853, 48 p., at https://doi.org/10.2737/PNW-GTR-853. |
Relative importance of abiotic, biotic, and disturbance drivers of plant community structure in the sagebrush steppe | R. M. Mitchell, J. D. Bakker, J. B. Vincent, G. M. Davies | 2017 | Mitchell, R.M., Bakker, J.D., Vincent, J.B., and Davies, G.M., 2017, Relative importance of abiotic, biotic, and disturbance drivers of plant community structure in the sagebrush steppe: Ecological Applications, v. 27, no. 3, p. 756–768, at https://doi.org/10.1002/eap.1479. |
Using geographic information to analyze wildland firefighter situational awareness—Impacts of spatial resolution on visibility assessment | K. A. Mistick, P. E. Dennison, M. J. Campbell, M. P. Thompson | 2022 | Mistick, K.A., Dennison, P.E., Campbell, M.J., and Thompson, M.P., 2022, Using geographic information to analyze wildland firefighter situational awareness—Impacts of spatial resolution on visibility assessment: Fire, v. 5, no. 5, article 151, at https://doi.org/10.3390/fire5050151. |
Fire severity and regeneration strategy influence shrub patch size and structure following disturbance | J. Minor, D. A. Falk, G. A. Barron-Gafford | 2017 | Minor, J., Falk, D.A., and Barron-Gafford, G.A., 2017, Fire severity and regeneration strategy influence shrub patch size and structure following disturbance: Forests, v. 8, no. 7, article 221, at https://doi.org/10.3390/f8070221. |
Greater sage-grouse habitat of Nevada and northeastern California—Integrating space use, habitat selection, and survival indices to guide areas for habitat management | Milligan, M.C., Coates, P.S., O’Neil, S.T., Brussee, B.E., Chenaille, M.P., Friend, D., Steele, K., Small, J.R., Bowden, T.S., Kosic, A.D., Miller, K. | 2024 | Milligan, M.C., Coates, P.S., O’Neil, S.T., Brussee, B.E., Chenaille, M.P., Friend, D., Steele, K., Small, J.R., Bowden, T.S., et al., 2024, Greater sage-grouse habitat of Nevada and northeastern California—Integrating space use, habitat selection, and survival indices to guide areas for habitat management: Reston, Va., U.S. Geological Survey Open-File Report 2024–1018, 70 p., at https://doi.org/10.3133/ofr20241018. |
Rapid response tools and datasets for post-fire erosion modeling—Linking remote sensing and process-based hydrological models to support post-fire remediation | Miller, M. E., Elliot, W. J., Endsley, K. A., Robichaud, P. R., Billmire, M. | 2014 | Miller, M.E., Elliot, W.J., Endsley, K.A., Robichaud, P.R., and Billmire, M., 2014, Rapid response tools and datasets for post-fire erosion modeling—Linking remote sensing and process-based hydrological models to support post-fire remediation, in ISPRS Technical Commission I Symposium, Denver, Colo., 17–20 November 2014, ISPRS Archives XL-1: International Society for Photogrammetry and Remote Sensing, p. 257–263, at https://doi.org/10.5194/isprsarchives-XL-1-257-2014. |
Rapid-response tools and datasets for post-fire remediation—Linking remote sensing and process-based hydrological models | M. E. Miller, W. J. Elliot, M. Billmire, P. R. Robichaud, K. A. Endsley | 2016 | Miller, M.E., Elliot, W.J., Billmire, M., Robichaud, P.R., and Endsley, K.A., 2016, Rapid-response tools and datasets for post-fire remediation—Linking remote sensing and process-based hydrological models: International Journal of Wildland Fire, v. 25, no. 10, p. 1061–1073, at https://doi.org/10.1071/wf15162. |
Socio-economic impact of the Rapid Response Erosion Database (RRED) | M. E. Miller, W. S. Breffle, M. Battaglia, D. Banach, P. R. Robichaud, W. J. Elliot, R. McClusky, I. S. Miller, M. Billmire | 2022 | Miller, M.E., Breffle, W.S., Battaglia, M., Banach, D., Robichaud, P.R., Elliot, W.J., McClusky, R., Miller, I.S., and Billmire, M., 2022, Socio-economic impact of the Rapid Response Erosion Database (RRED): Journal of Geoscience and Environment Protection, v. 10, no. 10, p. 103–125, at https://doi.org/10.4236/gep.2022.1010009. |
Rapid response tools and datasets for post-fire modeling—Linking Earth observations and process-based hydrological models to support post-fire remediation | Miller, M. E., Billmire, M., Elliot, W. J., Endsley, K. A., Robichaud, P. R. | 2015 | Miller, M.E., Billmire, M., Elliot, W.J., Endsley, K.A., and Robichaud, P.R., 2015, Rapid response tools and datasets for post-fire modeling—Linking Earth observations and process-based hydrological models to support post-fire remediation, in 36th International Symposium on Remote Sensing of Environment, Berlin, Germany, 11–15 May 2015, ISPRS Archives XL-7/W3: International Society for Photogrammetry and Remote Sensing, p. 469–476, at https://doi.org/10.5194/isprsarchives-XL-7-W3-469-2015. |
Trends and causes of severity, size, and number of fires in northwestern California, USA | J. D. Miller, C. N. Skinner, H. D. Safford, E. E. Knapp, C. M. Ramirez | 2012 | Miller, J.D., Skinner, C.N., Safford, H.D., Knapp, E.E., and Ramirez, C.M., 2012, Trends and causes of severity, size, and number of fires in northwestern California, USA: Ecological Applications, v. 22, no. 1, p. 184–203, at https://doi.org/10.1890/10-2108.1. |
Using one year post-fire fire severity assessments to estimate longer-term effects of fire in conifer forests of northern and eastern California, USA | J. D. Miller, H. D. Safford, K. R. Welch | 2016 | Miller, J.D., Safford, H.D., and Welch, K.R., 2016, Using one year post-fire fire severity assessments to estimate longer-term effects of fire in conifer forests of northern and eastern California, USA: Forest Ecology and Management, v. 382, p. 168–183, at https://doi.org/10.1016/j.foreco.2016.10.017. |
Trends in wildfire severity—1984 to 2010 in the Sierra Nevada, Modoc Plateau, and southern Cascades, California, USA | J. D. Miller, H. Safford | 2012 | Miller, J.D., and Safford, H., 2012, Trends in wildfire severity—1984 to 2010 in the Sierra Nevada, Modoc Plateau, and southern Cascades, California, USA: Fire Ecology, v. 8, no. 3, p. 41–57, at https://doi.org/10.4996/fireecology.0803041. |
Calibration and validation of immediate post-fire satellite-derived data to three severity metrics | J. D. Miller, B. Quayle | 2015 | Miller, J.D., and Quayle, B., 2015, Calibration and validation of immediate post-fire satellite-derived data to three severity metrics: Fire Ecology, v. 11, no. 2, p. 12–30, at https://doi.org/10.4996/fireecology.1102012. |
Differences in wildfires among ecoregions and land management agencies in the Sierra Nevada region, California, USA | J. D. Miller, B. M. Collins, J. A. Lutz, S. L. Stephens, J. W. van Wagtendonk, D. A. Yasuda | 2012 | Miller, J.D., Collins, B.M., Lutz, J.A., Stephens, S.L., van Wagtendonk, J.W., and Yasuda, D.A., 2012, Differences in wildfires among ecoregions and land management agencies in the Sierra Nevada region, California, USA: Ecosphere, v. 3, no. 9, p. 1–20, at https://doi.org/10.1890/ES12-00158.1. |
Different approaches make comparing studies of burn severity challenging—A review of methods used to link remotely sensed data with the Composite Burn Index | C. W. Miller, B. J. Harvey, V. R. Kane, L. M. Moskal, E. Alvarado | 2023 | Miller, C.W., Harvey, B.J., Kane, V.R., Moskal, L.M., and Alvarado, E., 2023, Different approaches make comparing studies of burn severity challenging—A review of methods used to link remotely sensed data with the Composite Burn Index: International Journal of Wildland Fire, v. 32, no. 4, p. 449–475, at https://doi.org/10.1071/wf22050. |
Progress in wilderness fire science—Embracing complexity | C. Miller, G. H. Aplet | 2016 | Miller, C., and Aplet, G.H., 2016, Progress in wilderness fire science—Embracing complexity: Journal of Forestry, v. 114, no. 3, p. 373–383, at https://doi.org/10.5849/jof.15-008. |
Logistic regression versus XGBoost for detecting burned areas using satellite images | A. F. Militino, H. Goyena, U. Pérez-Goya, M. D. Ugarte | 2024 | Militino, A.F., Goyena, H., Pérez-Goya, U., and Ugarte, M.D., 2024, Logistic regression versus XGBoost for detecting burned areas using satellite images: Environmental and Ecological Statistics, v. 31, p. 57–77, at https://doi.org/10.1007/s10651-023-00590-7. |
Relative importance of climate and mountain pine beetle outbreaks on the occurrence of large wildfires in the western USA | N. Mietkiewicz, D. Kulakowski | 2016 | Mietkiewicz, N., and Kulakowski, D., 2016, Relative importance of climate and mountain pine beetle outbreaks on the occurrence of large wildfires in the western USA: Ecological Applications, v. 26, no. 8, p. 2523–2535, at https://doi.org/10.1002/eap.1400. |
In the line of fire—Consequences of human-ignited wildfires to homes in the U.S. (1992–2015) | N. Mietkiewicz, J. K. Balch, T. Schoennagel, S. Leyk, L. A. St. Denis, B. A. Bradley | 2020 | Mietkiewicz, N., Balch, J.K., Schoennagel, T., Leyk, S., St. Denis, L.A., and Bradley, B.A., 2020, In the line of fire—Consequences of human-ignited wildfires to homes in the U.S. (1992–2015): Fire, v. 3, no. 3, article 50, at https://doi.org/10.3390/fire3030050. |
Quantifying changes in total and pyrogenic carbon stocks across fire severity gradients using active wildfire incidents | J. Miesel, A. Reiner, C. Ewell, B. Maestrini, M. Dickinson | 2018 | Miesel, J., Reiner, A., Ewell, C., Maestrini, B., and Dickinson, M., 2018, Quantifying changes in total and pyrogenic carbon stocks across fire severity gradients using active wildfire incidents: Frontiers in Earth Science, v. 6, article 41, at https://doi.org/10.3389/feart.2018.00041. |
Patterns of canopy and surface layer consumption in a boreal forest fire from repeat airborne lidar | A. Michael, C. M. Douglas, D. C. Bruce, A. Hans-Erik, B. Chad, P. Robert | 2017 | Michael, A., Douglas, C.M., Bruce, D.C., Hans-Erik, A., Chad, B., and Robert, P., 2017, Patterns of canopy and surface layer consumption in a boreal forest fire from repeat airborne lidar: Environmental Research Letters, v. 12, no. 6, article 065004, at https://doi.org/10.1088/1748-9326/aa6ade. |
The global lake area, climate, and population dataset—A new tool for addressing critical limnological questions | M. F. Meyer, M. R. Brousil, A. N. Cramer, B. P. Lanouette, J. C. Padowski, S. E. Hampton | 2020 | Meyer, M.F., Brousil, M.R., Cramer, A.N., Lanouette, B.P., Padowski, J.C., and Hampton, S.E., 2020, The global lake area, climate, and population dataset—A new tool for addressing critical limnological questions: Limnology and Oceanography Bulletin, v. 29, no. 4, p. 110–116, at https://doi.org/10.1002/lob.10406. |
Forest fire severity patterns of resource objective wildfires in the southern Sierra Nevada | M. D. Meyer | 2015 | Meyer, M.D., 2015, Forest fire severity patterns of resource objective wildfires in the southern Sierra Nevada: Journal of Forestry, v. 113, no. 1, p. 49–56, at https://doi.org/10.5849/jof.14-084. |
Circuit theory to estimate natal dispersal routes and functional landscape connectivity for an endangered small mammal | M. J. Merrick, J. L. Koprowski | 2017 | Merrick, M.J., and Koprowski, J.L., 2017, Circuit theory to estimate natal dispersal routes and functional landscape connectivity for an endangered small mammal: Landscape Ecology, v. 32, no. 6, p. 1163–1179, at https://doi.org/10.1007/s10980-017-0521-z. |
Non-equilibrium in plant distribution models—Only an issue for introduced or dispersal limited species? | D. R. Menuz, K. M. Kettenring, C. P. Hawkins, D. R. Cutler | 2015 | Menuz, D.R., Kettenring, K.M., Hawkins, C.P., and Cutler, D.R., 2015, Non-equilibrium in plant distribution models—Only an issue for introduced or dispersal limited species?: Ecography, v. 38, no. 3, p. 231–240, at https://doi.org/10.1111/ecog.00928. |
The importance of roads, nutrients, and climate for invasive plant establishment in riparian areas in the northwestern United States | D. R. Menuz, K. M. Kettenring | 2013 | Menuz, D.R., and Kettenring, K.M., 2013, The importance of roads, nutrients, and climate for invasive plant establishment in riparian areas in the northwestern United States: Biological Invasions, v. 15, no. 7, p. 1601–1612, at https://doi.org/10.1007/s10530-012-0395-6. |
Nevada’s forest resources, 2004–2013 | Menlove, J., Shaw, J. D., Witt, C., Werstak, C. E., Jr., Justin DeRose, R., Goeking, S. A., Amacher, M. C., Morgan, T. A., Sorenson, C. B. | 2016 | Menlove, J., Shaw, J.D., Witt, C., Werstak, C.E., Jr., Justin DeRose, R., Goeking, S.A., Amacher, M.C., Morgan, T.A., and Sorenson, C.B., 2016, Nevada’s forest resources, 2004–2013: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-22, 167 p., at https://doi.org/10.2737/RMRS-RB-22. |
Montana’s forest resources, 2003–2009 | Menlove, J., Shaw, J. D., Thompson, M. T., Witt, C., Amacher, M. C., Morgan, T. A., Sorenson, C., McIver, C., Werstak, C. | 2012 | Menlove, J., Shaw, J.D., Thompson, M.T., Witt, C., Amacher, M.C., Morgan, T.A., Sorenson, C., McIver, C., and Werstak, C., 2012, Montana’s forest resources, 2003–2009: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-15, 140 p., at https://doi.org/10.2737/RMRS-RB-15. |
Snow-cover remote sensing of conifer tree recovery in high-severity burn patches | C. Menick, W. Tinkham, C. Hoffman, M. Vanderhoof, J. Vogeler | 2024 | Menick, C., Tinkham, W., Hoffman, C., Vanderhoof, M., and Vogeler, J., 2024, Snow-cover remote sensing of conifer tree recovery in high-severity burn patches: Remote Sensing of Environment, v. 305, article 114114, at https://doi.org/10.1016/j.rse.2024.114114. |
Black Hills wildfires mapping post-fire conifer regeneration using snow-on imagery | Menick, C., Seldon, Y., Stuckmeyer, H., Rogers, H. | 2022 | Menick, C., Seldon, Y., Stuckmeyer, H., and Rogers, H., 2022, Black Hills wildfires mapping post-fire conifer regeneration using snow-on imagery: Fort Collins, Colo., NASA DEVELOP National Program NASA DEVELOP Technical Report, 14 p., at https://ntrs.nasa.gov/api/citations/20220014676/downloads/2022Sum_CO_BlackHillsWildfires_TechPaper_FD-final.docx.pdf. |
Using high spatial resolution satellite imagery to map forest burn severity across spatial scales in a Pine Barrens ecosystem | R. Meng, J. Wu, K. L. Schwager, F. Zhao, P. E. Dennison, B. D. Cook, K. Brewster, T. M. Green, S. P. Serbin | 2017 | Meng, R., Wu, J., Schwager, K.L., Zhao, F., Dennison, P.E., Cook, B.D., Brewster, K., Green, T.M., and Serbin, S.P., 2017, Using high spatial resolution satellite imagery to map forest burn severity across spatial scales in a Pine Barrens ecosystem: Remote Sensing of Environment, v. 191, p. 95–109, at https://doi.org/10.1016/j.rse.2017.01.016. |
Landsat-based monitoring of southern pine beetle infestation severity and severity change in a temperate mixed forest | R. Meng, R. Gao, F. Zhao, C. Huang, R. Sun, Z. Lv, Z. Huang | 2022 | Meng, R., Gao, R., Zhao, F., Huang, C., Sun, R., Lv, Z., and Huang, Z., 2022, Landsat-based monitoring of southern pine beetle infestation severity and severity change in a temperate mixed forest: Remote Sensing of Environment, v. 269, article 112847, at https://doi.org/10.1016/j.rse.2021.112847. |
Effects of fire severity and post-fire climate on short-term vegetation recovery of mixed-conifer and red fir forests in the Sierra Nevada Mountains of California | R. Meng, P. E. Dennison, C. Huang, M. A. Moritz, C. D'Antonio | 2015 | Meng, R., Dennison, P.E., Huang, C., Moritz, M.A., and D'Antonio, C., 2015, Effects of fire severity and post-fire climate on short-term vegetation recovery of mixed-conifer and red fir forests in the Sierra Nevada Mountains of California: Remote Sensing of Environment, v. 171, p. 311–325, at https://doi.org/10.1016/j.rse.2015.10.024. |
Remote sensing analysis of vegetation recovery following short-interval fires in southern California shrublands | R. Meng, P. E. Dennison, C. M. D'Antonio, M. A. Moritz | 2014 | Meng, R., Dennison, P.E., D'Antonio, C.M., and Moritz, M.A., 2014, Remote sensing analysis of vegetation recovery following short-interval fires in southern California shrublands: PLoS ONE, v. 9, no. 10, article e110637, at https://doi.org/10.1371/journal.pone.0110637. |
Landscape-scale simulation of heterogeneous fire effects on pyrogenic carbon emissions, tree mortality, and net ecosystem production | G. W. Meigs, D. P. Turner, W. D. Ritts, Z. Yang, B. E. Law | 2011 | Meigs, G.W., Turner, D.P., Ritts, W.D., Yang, Z., and Law, B.E., 2011, Landscape-scale simulation of heterogeneous fire effects on pyrogenic carbon emissions, tree mortality, and net ecosystem production: Ecosystems, v. 14, no. 5, p. 758–775, at https://doi.org/10.1007/s10021-011-9444-8. |
Composition and structure of forest fire refugia—What are the ecosystem legacies across burned landscapes? | G. W. Meigs, M. A. Krawchuk | 2018 | Meigs, G.W., and Krawchuk, M.A., 2018, Composition and structure of forest fire refugia—What are the ecosystem legacies across burned landscapes?: Forests, v. 9, no. 5, article 243, at https://doi.org/10.3390/f9050243. |
Spatiotemporal dynamics of recent mountain pine beetle and western spruce budworm outbreaks across the Pacific Northwest Region, USA | G. W. Meigs, R. E. Kennedy, A. N. Gray, M. J. Gregory | 2015 | Meigs, G.W., Kennedy, R.E., Gray, A.N., and Gregory, M.J., 2015, Spatiotemporal dynamics of recent mountain pine beetle and western spruce budworm outbreaks across the Pacific Northwest Region, USA: Forest Ecology and Management, v. 339, p. 71–86, at https://doi.org/10.1016/j.foreco.2014.11.030. |
A Landsat time series approach to characterize bark beetle and defoliator impacts on tree mortality and surface fuels in conifer forests | G. W. Meigs, R. E. Kennedy, W. B. Cohen | 2011 | Meigs, G.W., Kennedy, R.E., and Cohen, W.B., 2011, A Landsat time series approach to characterize bark beetle and defoliator impacts on tree mortality and surface fuels in conifer forests: Remote Sensing of Environment, v. 115, no. 12, p. 3707–3718, at https://doi.org/10.1016/j.rse.2011.09.009. |
Influence of topography and fuels on fire refugia probability under varying fire weather conditions in forests of the Pacific Northwest, USA | G. W. Meigs, C. J. Dunn, S. A. Parks, M. A. Krawchuk | 2020 | Meigs, G.W., Dunn, C.J., Parks, S.A., and Krawchuk, M.A., 2020, Influence of topography and fuels on fire refugia probability under varying fire weather conditions in forests of the Pacific Northwest, USA: Canadian Journal of Forest Research, v. 50, no. 7, p. 636–647, at https://doi.org/10.1139/cjfr-2019-0406. |
Drought, wildfire and forest transformation—Characterizing trailing edge forests in the eastern Cascade Range, Washington, USA | G. W. Meigs, M. J. Case, D. J. Churchill, C. M. Hersey, S. M. A. Jeronimo, L. A. C. Smith, D. Thom | 2023 | Meigs, G.W., Case, M.J., Churchill, D.J., Hersey, C.M., Jeronimo, S.M.A., Smith, L.A.C., and Thom, D., 2023, Drought, wildfire and forest transformation—Characterizing trailing edge forests in the eastern Cascade Range, Washington, USA: Forestry—An International Journal of Forest Research, v. 96, no. 3, p. 340–354, at https://doi.org/10.1093/forestry/cpac046. |
Does wildfire likelihood increase following insect outbreaks in conifer forests? | G. W. Meigs, J. L. Campbell, H. S. J. Zald, J. D. Bailey, D. C. Shaw, R. E. Kennedy | 2015 | Meigs, G.W., Campbell, J.L., Zald, H.S.J., Bailey, J.D., Shaw, D.C., and Kennedy, R.E., 2015, Does wildfire likelihood increase following insect outbreaks in conifer forests?: Ecosphere, v. 6, no. 7, article 118, at https://doi.org/10.1890/ES15-00037.1. |
Spatiotemporal patterns of unburned areas within fire perimeters in the northwestern United States from 1984 to 2014 | A. J. H. Meddens, C. A. Kolden, J. A. Lutz, J. T. Abatzoglou, A. T. Hudak | 2018 | Meddens, A.J.H., Kolden, C.A., Lutz, J.A., Abatzoglou, J.T., and Hudak, A.T., 2018, Spatiotemporal patterns of unburned areas within fire perimeters in the northwestern United States from 1984 to 2014: Ecosphere, v. 9, no. 2, article e02029, at https://doi.org/10.1002/ecs2.2029. |
Detecting unburned areas within wildfire perimeters using Landsat and ancillary data across the northwestern United States | A. J. H. Meddens, C. A. Kolden, J. A. Lutz | 2016 | Meddens, A.J.H., Kolden, C.A., and Lutz, J.A., 2016, Detecting unburned areas within wildfire perimeters using Landsat and ancillary data across the northwestern United States: Remote Sensing of Environment, v. 186, p. 275–285, at https://doi.org/10.1016/j.rse.2016.08.023. |
Modelling species distributions and environmental suitability highlights risk of plant invasions in western United States | D. E. McMahon, A. K. Urza, J. L. Brown, C. Phelan, J. C. Chambers | 2021 | McMahon, D.E., Urza, A.K., Brown, J.L., Phelan, C., and Chambers, J.C., 2021, Modelling species distributions and environmental suitability highlights risk of plant invasions in western United States: Diversity and Distributions, v. 27, no. 4, p. 710–728, at https://doi.org/10.1111/ddi.13232. |
Food webs for three burn severities after wildfire in the Eldorado National Forest, California | J. P. McLaughlin, J. W. Schroeder, A. M. White, K. Culhane, H. E. Mirts, G. L. Tarbill, L. Sire, M. Page, E. J. Baker, M. Moritz, J. Brashares, H. S. Young, R. Sollmann | 2022 | McLaughlin, J.P., Schroeder, J.W., White, A.M., Culhane, K., Mirts, H.E., Tarbill, G.L., Sire, L., Page, M., Baker, E.J., et al., 2022, Food webs for three burn severities after wildfire in the Eldorado National Forest, California: Scientific Data, v. 9, no. 1, article 384, at https://doi.org/10.1038/s41597-022-01220-w. |
Fire as a fundamental ecological process—Research advances and frontiers | K. K. McLauchlan, P. E. Higuera, J. Miesel, B. M. Rogers, J. Schweitzer, J. K. Shuman, A. J. Tepley, J. M. Varner, T. T. Veblen, S. A. Adalsteinsson, J. K. Balch, P. Baker, E. Batllori, E. Bigio, P. Brando, M. Cattau, M. L. Chipman, J. Coen, R. Crandall, L. Daniels, N. Enright, W. S. Gross, B. J. Harvey, J. A. Hatten, S. Hermann, R. E. Hewitt, L. N. Kobziar, J. B. Landesmann, M. M. Loranty, S. Y. Maezumi, L. Mearns, M. Moritz, J. A. Myers, J. G. Pausas, A. F. A. Pellegrini, W. J. Platt, J. Roozeboom, H. Safford, F. Santos, R. M. Scheller, R. L. Sherriff, K. G. Smith, M. D. Smith, A. C. Watts | 2020 | McLauchlan, K.K., Higuera, P.E., Miesel, J., Rogers, B.M., Schweitzer, J., Shuman, J.K., Tepley, A.J., Varner, J.M., Veblen, T.T., et al., 2020, Fire as a fundamental ecological process—Research advances and frontiers: Journal of Ecology, v. 108, no. 5, p. 2047–2069, at https://doi.org/10.1111/1365-2745.13403. |
Systematic review and meta-analysis of fire regime research in ponderosa pine (Pinus ponderosa) ecosystems, Colorado, USA | S. T. McKinney | 2019 | McKinney, S.T., 2019, Systematic review and meta-analysis of fire regime research in ponderosa pine (Pinus ponderosa) ecosystems, Colorado, USA: Fire Ecology, v. 15, no. 1, article 38, at https://doi.org/10.1186/s42408-019-0056-6. |
Burn severity mapping in Australia 2009 | McKinley, R., Clark, J., Lecker, J. | 2012 | McKinley, R., Clark, J., and Lecker, J., 2012, Burn severity mapping in Australia 2009, in XXII ISPRS Congress, Melbourne, Australia, 25 August – 01 September 2012, ISPRS Archives XXXIX-B8: International Society for Photogrammetry and Remote Sensing, p. 51–54, at https://doi.org/10.5194/isprsarchives-XXXIX-B8-51-2012. |
Post-fire aspen (Populus tremuloides) regeneration varies in response to winter precipitation across a regional climate gradient | S. K. McIlroy, D. J. Shinneman | 2020 | McIlroy, S.K., and Shinneman, D.J., 2020, Post-fire aspen (Populus tremuloides) regeneration varies in response to winter precipitation across a regional climate gradient: Forest Ecology and Management, v. 455, article 117681, at https://doi.org/10.1016/j.foreco.2019.117681. |
Pyrogeography of the western Great Plains—A 40-year history of fire in semi-arid rangelands | D. A. McGranahan, C. L. Wonkka | 2024 | McGranahan, D.A., and Wonkka, C.L., 2024, Pyrogeography of the western Great Plains—A 40-year history of fire in semi-arid rangelands: Fire, v. 7, no. 1, article 32, at https://doi.org/10.3390/fire7010032. |
Fuel properties of effective greenstrips in simulated cheatgrass fires | D. A. McGranahan, C. L. Wonkka | 2022 | McGranahan, D.A., and Wonkka, C.L., 2022, Fuel properties of effective greenstrips in simulated cheatgrass fires: Environmental Management, v. 70, p. 319–328, at https://doi.org/10.1007/s00267-022-01659-y. |
Future regional increases in simultaneous large western USA wildfires | S. McGinnis, L. Kessenich, L. Mearns, A. Cullen, H. Podschwit, M. Bukovsky | 2023 | McGinnis, S., Kessenich, L., Mearns, L., Cullen, A., Podschwit, H., and Bukovsky, M., 2023, Future regional increases in simultaneous large western USA wildfires: International Journal of Wildland Fire, v. 32, no. 9, p. 1304–1314, at https://doi.org/10.1071/WF22107. |
Establishing relationships between drought indices and wildfire danger outputs—A test case for the California-Nevada Drought Early Warning System | D. McEvoy, M. Hobbins, T. Brown, K. VanderMolen, T. Wall, J. Huntington, M. Svoboda | 2019 | McEvoy, D., Hobbins, M., Brown, T., VanderMolen, K., Wall, T., Huntington, J., and Svoboda, M., 2019, Establishing relationships between drought indices and wildfire danger outputs—A test case for the California-Nevada Drought Early Warning System: Climate, v. 7, no. 4, article 52, at https://doi.org/10.3390/cli7040052. |
Hazards of risk—Identifying plausible community wildfire disasters in low-frequency fire regimes | A. McEvoy, B. K. Kerns, J. B. Kim | 2021 | McEvoy, A., Kerns, B.K., and Kim, J.B., 2021, Hazards of risk—Identifying plausible community wildfire disasters in low-frequency fire regimes: Forests, v. 12, no. 7, article 934, at https://doi.org/10.3390/f12070934. |
Effects of forest disturbance on water yield and peak flow in low?relief glaciated catchments assessed with Bayesian parameter estimation | Z. P. McEachran, G. C. Reese, D. L. Karwan, R. A. Slesak, J. Vogeler | 2023 | McEachran, Z.P., Reese, G.C., Karwan, D.L., Slesak, R.A., and Vogeler, J., 2023, Effects of forest disturbance on water yield and peak flow in low?relief glaciated catchments assessed with Bayesian parameter estimation: Hydrological Processes, v. 37, no. 8, article e14956, at https://doi.org/10.1002/hyp.14956. |
Do lakes feel the burn? Ecological consequences of increasing exposure of lakes to fire in the continental United States | I. M. McCullough, K. S. Cheruvelil, J. F. Lapierre, N. R. Lottig, M. A. Moritz, J. Stachelek, P. A. Soranno | 2019 | McCullough, I.M., Cheruvelil, K.S., Lapierre, J.F., Lottig, N.R., Moritz, M.A., Stachelek, J., and Soranno, P.A., 2019, Do lakes feel the burn? Ecological consequences of increasing exposure of lakes to fire in the continental United States: Global Change Biology, v. 25, no. 9, p. 2841–2854, at https://doi.org/10.1111/gcb.14732. |
Fire characteristics and hydrologic connectivity influence short?term responses of north temperate lakes to wildfire | I. M. McCullough, J. A. Brentrup, T. Wagner, J. F. Lapierre, J. Henneck, A. M. Paul, M. Belair, M. A. Moritz, C. T. Filstrup | 2023 | McCullough, I.M., Brentrup, J.A., Wagner, T., Lapierre, J.F., Henneck, J., Paul, A.M., Belair, M., Moritz, M.A., and Filstrup, C.T., 2023, Fire characteristics and hydrologic connectivity influence short?term responses of north temperate lakes to wildfire: Geophysical Research Letters, v. 50, no. 16, article e2023GL103953, at https://doi.org/10.1029/2023gl103953. |
Wildfire and infant health—A geospatial approach to estimating the health impacts of wildfire smoke exposure | S. J. McCoy, X. Zhao | 2020 | McCoy, S.J., and Zhao, X., 2020, Wildfire and infant health—A geospatial approach to estimating the health impacts of wildfire smoke exposure: Applied Economics Letters, v. 28, no. 1, p. 32–37, at https://doi.org/10.1080/13504851.2020.1730747. |
Wildfire risk, salience & housing demand | S. J. McCoy, R. P. Walsh | 2018 | McCoy, S.J., and Walsh, R.P., 2018, Wildfire risk, salience & housing demand: Journal of Environmental Economics and Management, v. 91, p. 203–228, at https://doi.org/10.1016/j.jeem.2018.07.005. |
Effects of wildfire destruction on migration, consumer credit, and financial distress | McConnell, Kathryn, Whitaker, Stephan D., Fussell, Elizabeth, DeWaard, Jack, Curtis, Katherine, Price, Kobie, St. Denis, Lise, Balch, Jennifer | 2021 | McConnell, K., Whitaker, S.D., Fussell, E., DeWaard, J., Curtis, K., Price, K., St. Denis, L., and Balch, J., 2021, Effects of wildfire destruction on migration, consumer credit, and financial distress: Federal Reserve Bank of Cleveland Working Paper No. 21-29, 58 p., at https://doi.org/10.26509/frbc-wp-202129. |
Evaluating the Mid-Infrared Bi-spectral Index for improved assessment of low-severity fire effects in a conifer forest | T. R. McCarley, A. M. S. Smith, C. A. Kolden, J. Kreitler | 2018 | McCarley, T.R., Smith, A.M.S., Kolden, C.A., and Kreitler, J., 2018, Evaluating the Mid-Infrared Bi-spectral Index for improved assessment of low-severity fire effects in a conifer forest: International Journal of Wildland Fire, v. 27, no. 6, p. 407–412, at https://doi.org/10.1071/Wf17137. |
Landscape-scale quantification of fire-induced change in canopy cover following mountain pine beetle outbreak and timber harvest | T. R. McCarley, C. A. Kolden, N. M. Vaillant, A. T. Hudak, A. M. S. Smith, J. Kreitler | 2017 | McCarley, T.R., Kolden, C.A., Vaillant, N.M., Hudak, A.T., Smith, A.M.S., and Kreitler, J., 2017, Landscape-scale quantification of fire-induced change in canopy cover following mountain pine beetle outbreak and timber harvest: Forest Ecology and Management, v. 391, p. 164–175, at https://doi.org/10.1016/j.foreco.2017.02.015. |
Predicting fine-scale forage distribution to inform ungulate nutrition | T. R. McCarley, T. M. Ball, J. L. Aycrigg, E. K. Strand, L. K. Svancara, J. S. Horne, T. N. Johnson, M. K. Lonneker, M. Hurley | 2020 | McCarley, T.R., Ball, T.M., Aycrigg, J.L., Strand, E.K., Svancara, L.K., Horne, J.S., Johnson, T.N., Lonneker, M.K., and Hurley, M., 2020, Predicting fine-scale forage distribution to inform ungulate nutrition: Ecological Informatics, v. 60, article 101170, at https://doi.org/10.1016/j.ecoinf.2020.101170. |
Wildfire and topography impacts on snow accumulation and retention in montane forests | J. D. Maxwell, A. Call, S. B. St. Clair | 2019 | Maxwell, J.D., Call, A., and St. Clair, S.B., 2019, Wildfire and topography impacts on snow accumulation and retention in montane forests: Forest Ecology and Management, v. 432, p. 256–263, at https://doi.org/10.1016/j.foreco.2018.09.021. |
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Assessing the effectiveness of landscape-scale forest adaptation actions to improve resilience under projected climate change | C. J. Maxwell, R. M. Scheller, K. N. Wilson, P. N. Manley | 2022 | Maxwell, C.J., Scheller, R.M., Wilson, K.N., and Manley, P.N., 2022, Assessing the effectiveness of landscape-scale forest adaptation actions to improve resilience under projected climate change: Frontiers in Forests and Global Change, v. 5, article 740869, at https://doi.org/10.3389/ffgc.2022.740869. |
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Comparison of model-assisted endogenous poststratification methods for estimation of above-ground biomass change in Oregon, USA | F. Mauro, V. J. Monleon, A. N. Gray, O. Kuegler, H. Temesgen, A. T. Hudak, P. A. Fekety, Z. Yang | 2022 | Mauro, F., Monleon, V.J., Gray, A.N., Kuegler, O., Temesgen, H., Hudak, A.T., Fekety, P.A., and Yang, Z., 2022, Comparison of model-assisted endogenous poststratification methods for estimation of above-ground biomass change in Oregon, USA: Remote Sensing, v. 14, no. 23, article 6024, at https://doi.org/10.3390/rs14236024. |
Arceuthobium microcarpum (Viscaceae)—Morphological evidence for continued species recognition and discrimination from Arceuthobium campylopodum | R. L. Mathiasen, S. C. Kenaley, J. M. Scott | 2018 | Mathiasen, R.L., Kenaley, S.C., and Scott, J.M., 2018, Arceuthobium microcarpum (Viscaceae)—Morphological evidence for continued species recognition and discrimination from Arceuthobium campylopodum: Phytologia, v. 100, no. 1, p. 71–90, at https://www.phytologia.org/uploads/2/3/4/2/23422706/100_1_71-90mathiasen.comments.revised_mathisaen3-18-18.pdf. |
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Topography, climate and fire history regulate wildfire activity in the Alaskan tundra | A. Masrur, A. Taylor, L. Harris, J. Barnes, A. Petrov | 2022 | Masrur, A., Taylor, A., Harris, L., Barnes, J., and Petrov, A., 2022, Topography, climate and fire history regulate wildfire activity in the Alaskan tundra: Journal of Geophysical Research—Biogeosciences, v. 127, no. 3, article e2021JG006608, at https://doi.org/10.1029/2021JG006608. |
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Characterizing persistent unburned islands within the Inland Northwest USA | A. J. Martinez, A. J. H. Meddens, C. A. Kolden, E. K. Strand, A. T. Hudak | 2019 | Martinez, A.J., Meddens, A.J.H., Kolden, C.A., Strand, E.K., and Hudak, A.T., 2019, Characterizing persistent unburned islands within the Inland Northwest USA: Fire Ecology, v. 15, no. 1, article 20, at https://doi.org/10.1186/s42408-019-0036-x. |
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Assess the formation of disinfection by-products from pyrogenic dissolved organic matter (pyDOM)—Impact of wildfire on the water quality of forest watershed | Z. Li, P. R. V. Samonte, H. Cao, J. R. Miesel, W. Xu | 2023 | Li, Z., Samonte, P.R.V., Cao, H., Miesel, J.R., and Xu, W., 2023, Assess the formation of disinfection by-products from pyrogenic dissolved organic matter (pyDOM)—Impact of wildfire on the water quality of forest watershed: Science of the Total Environment, v. 898, article 165496, at https://doi.org/10.1016/j.scitotenv.2023.165496. |
The impacts of wildfires of different burn severities on vegetation structure across the western United States rangelands | Z. Li, J. P. Angerer, X. B. Wu | 2022 | Li, Z., Angerer, J.P., and Wu, X.B., 2022, The impacts of wildfires of different burn severities on vegetation structure across the western United States rangelands: Science of the Total Environment, v. 845, article 157214, at https://doi.org/10.1016/j.scitotenv.2022.157214. |
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Prefire vegetation structure of high severity wildfires in nonherbaceous?dominated rangelands in the western United States | Z. Li, J. Angerer, X. Ben Wu | 2022 | Li, Z., Angerer, J., and Ben Wu, X., 2022, Prefire vegetation structure of high severity wildfires in nonherbaceous?dominated rangelands in the western United States: Earth's Future, v. 10, no. 10, article e2021EF002624, at https://doi.org/10.1029/2021ef002624. |
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Estimation of biomass-burning emissions by fusing the fire radiative power retrievals from polar-orbiting and geostationary satellites across the conterminous United States | F. Li, X. Zhang, D. P. Roy, S. Kondragunta | 2019 | Li, F., Zhang, X., Roy, D.P., and Kondragunta, S., 2019, Estimation of biomass-burning emissions by fusing the fire radiative power retrievals from polar-orbiting and geostationary satellites across the conterminous United States: Atmospheric Environment, v. 211, p. 274–287, at https://doi.org/10.1016/j.atmosenv.2019.05.017. |
Investigation of the fire radiative energy biomass combustion coefficient—A comparison of polar and geostationary satellite retrievals over the conterminous United States | F. Li, X. Zhang, S. Kondragunta, D. P. Roy | 2018 | Li, F., Zhang, X., Kondragunta, S., and Roy, D.P., 2018, Investigation of the fire radiative energy biomass combustion coefficient—A comparison of polar and geostationary satellite retrievals over the conterminous United States: Journal of Geophysical Research—Biogeosciences, v. 123, no. 2, p. 722–739, at https://doi.org/10.1002/2017JG004279. |
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Indicators of burn severity at extended temporal scales—A decade of ecosystem response in mixed-conifer forests of western Montana | S. A. Lewis, A. T. Hudak, P. R. Robichaud, P. Morgan, K. L. Satterberg, E. K. Strand, A. M. S. Smith, J. A. Zamudio, L. B. Lentile | 2017 | Lewis, S.A., Hudak, A.T., Robichaud, P.R., Morgan, P., Satterberg, K.L., Strand, E.K., Smith, A.M.S., Zamudio, J.A., and Lentile, L.B., 2017, Indicators of burn severity at extended temporal scales—A decade of ecosystem response in mixed-conifer forests of western Montana: International Journal of Wildland Fire, v. 26, no. 9, p. 755–771, at https://doi.org/10.1071/WF17019. |
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Digital soil mapping for fire prediction and management in rangelands | M. R. Levi, B. T. Bestelmeyer | 2018 | Levi, M.R., and Bestelmeyer, B.T., 2018, Digital soil mapping for fire prediction and management in rangelands: Fire Ecology, v. 14, no. 2, article 11, at https://doi.org/10.1186/s42408-018-0018-4. |
Biophysical influences on the spatial distribution of fire in the desert grassland region of the southwestern USA | M. R. Levi, B. T. Bestelmeyer | 2016 | Levi, M.R., and Bestelmeyer, B.T., 2016, Biophysical influences on the spatial distribution of fire in the desert grassland region of the southwestern USA: Landscape Ecology, v. 31, no. 9, p. 2079–2095, at https://doi.org/10.1007/s10980-016-0383-9. |
Mixed-severity wildfire and habitat of an old-forest obligate | D. B. Lesmeister, S. G. Sovern, R. J. Davis, D. M. Bell, M. J. Gregory, J. C. Vogeler | 2019 | Lesmeister, D.B., Sovern, S.G., Davis, R.J., Bell, D.M., Gregory, M.J., and Vogeler, J.C., 2019, Mixed-severity wildfire and habitat of an old-forest obligate: Ecosphere, v. 10, no. 4, article e02696, at https://doi.org/10.1002/ecs2.2696. |
Evaluating fireline effectiveness across large wildfire events in north-central Washington State | R. E. Lemons, S. J. Prichard, B. K. Kerns | 2023 | Lemons, R.E., Prichard, S.J., and Kerns, B.K., 2023, Evaluating fireline effectiveness across large wildfire events in north-central Washington State: Fire Ecology, v. 19, no. 1, article 8, at https://doi.org/10.1186/s42408-023-00167-6. |
The effects of seed source health on whitebark pine (Pinus albicaulis) regeneration density after wildfire | S. B. Leirfallom, R. E. Keane, D. F. Tomback, S. Z. Dobrowski | 2015 | Leirfallom, S.B., Keane, R.E., Tomback, D.F., and Dobrowski, S.Z., 2015, The effects of seed source health on whitebark pine (Pinus albicaulis) regeneration density after wildfire: Canadian Journal of Forest Research, v. 45, no. 11, p. 1597–1606, at https://doi.org/10.1139/cjfr-2015-0043. |
Monitoring the effects of forest restoration treatments on post-fire vegetation recovery with MODIS multitemporal data | W. J. D. Van Leeuwen | 2008 | Van Leeuwen, W.J.D., 2008, Monitoring the effects of forest restoration treatments on post-fire vegetation recovery with MODIS multitemporal data: Sensors, v. 8, no. 3, p. 2017–2042, at https://doi.org/10.3390/s8032017. |
Reductions in national forest campground reservation demand from wildfire | M. C. Lee, J. F. Suter, J. Bayham | 2023 | Lee, M.C., Suter, J.F., and Bayham, J., 2023, Reductions in national forest campground reservation demand from wildfire: Journal of Agricultural and Resource Economics, v. 48, no. 3, p. 483–499, at https://doi.org/10.22004/ag.econ.322851. |
Carbon implications of current and future effects of drought, fire and management on Pacific Northwest forests | B. E. Law, R. H. Waring | 2015 | Law, B.E., and Waring, R.H., 2015, Carbon implications of current and future effects of drought, fire and management on Pacific Northwest forests: Forest Ecology and Management, v. 355, p. 4–14, at https://doi.org/10.1016/j.foreco.2014.11.023. |
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Patterns and drivers of early conifer regeneration following stand-replacing wildfire in Pacific Northwest (USA) temperate maritime forests | M. M. Laughlin, L. K. Rangel-Parra, J. E. Morris, D. C. Donato, J. S. Halofsky, B. J. Harvey | 2023 | Laughlin, M.M., Rangel-Parra, L.K., Morris, J.E., Donato, D.C., Halofsky, J.S., and Harvey, B.J., 2023, Patterns and drivers of early conifer regeneration following stand-replacing wildfire in Pacific Northwest (USA) temperate maritime forests: Forest Ecology and Management, v. 549, article 121491, at https://doi.org/10.1016/j.foreco.2023.121491. |
Trends in forest structure restoration need over three decades with increasing wildfire activity in the interior Pacific Northwest US | M. M. Laughlin, J. D. Bakker, D. J. Churchill, M. J. Gregory, T. DeMeo, E. C. Alvarado, B. J. Harvey | 2023 | Laughlin, M.M., Bakker, J.D., Churchill, D.J., Gregory, M.J., DeMeo, T., Alvarado, E.C., and Harvey, B.J., 2023, Trends in forest structure restoration need over three decades with increasing wildfire activity in the interior Pacific Northwest US: Forest Ecology and Management, v. 527, article 120607, at https://doi.org/10.1016/j.foreco.2022.120607. |
Dry conifer forest restoration benefits Colorado Front Range avian communities | Q. S. Latif, R. L. Truex, R. A. Sparks, D. C. Pavlacky, Jr. | 2020 | Latif, Q.S., Truex, R.L., Sparks, R.A., and Pavlacky, D.C., Jr., 2020, Dry conifer forest restoration benefits Colorado Front Range avian communities: Ecological Applications, v. 30, no. 6, article e02142, at https://doi.org/10.1002/eap.2142. |
Avian relationships with wildfire at two dry forest locations with different historical fire regimes | Q. S. Latif, J. S. Sanderlin, V. A. Saab, W. M. Block, J. G. Dudley | 2016 | Latif, Q.S., Sanderlin, J.S., Saab, V.A., Block, W.M., and Dudley, J.G., 2016, Avian relationships with wildfire at two dry forest locations with different historical fire regimes: Ecosphere, v. 7, no. 5, article e01346, at https://doi.org/10.1002/ecs2.1346. |
Transferability of habitat suitability models for nesting woodpeckers associated with wildfire | Q. S. Latif, V. A. Saab, J. P. Hollenbeck, J. G. Dudley | 2016 | Latif, Q.S., Saab, V.A., Hollenbeck, J.P., and Dudley, J.G., 2016, Transferability of habitat suitability models for nesting woodpeckers associated with wildfire: The Condor, v. 118, no. 4, p. 766–790, at https://doi.org/10.1650/condor-16-86.1. |
Development and evaluation of habitat suitability models for nesting white-headed woodpecker (Dryobates albolarvatus) in burned forest | Q. S. Latif, V. A. Saab, J. G. Dudley, A. Markus, K. Mellen-McLean | 2020 | Latif, Q.S., Saab, V.A., Dudley, J.G., Markus, A., and Mellen-McLean, K., 2020, Development and evaluation of habitat suitability models for nesting white-headed woodpecker (Dryobates albolarvatus) in burned forest: PLoS ONE, v. 15, no. 5, article e0233043, at https://doi.org/10.1371/journal.pone.0233043. |
Ensemble modeling to predict habitat suitability for a large-scale disturbance specialist | Q. S. Latif, V. A. Saab, J. G. Dudley, J. P. Hollenbeck | 2013 | Latif, Q.S., Saab, V.A., Dudley, J.G., and Hollenbeck, J.P., 2013, Ensemble modeling to predict habitat suitability for a large-scale disturbance specialist: Ecology and Evolution, v. 3, no. 13, p. 4348–4364, at https://doi.org/10.1002/ece3.790. |
Simulated treatment effects on bird communities inform landscape-scale dry conifer forest management | Q. S. Latif, J. B. Cannon, E. J. Chabot, R. A. Sparks | 2022 | Latif, Q.S., Cannon, J.B., Chabot, E.J., and Sparks, R.A., 2022, Simulated treatment effects on bird communities inform landscape-scale dry conifer forest management: Ecological Applications, v. 32, no. 4, article e2555, at https://doi.org/10.1002/eap.2555. |
Landscape evaluations and prescriptions for post-fire landscapes, Final Report | Larson, A.J., Cansler, C.A., Kane, V.R., Churchill, D.J., Hessburg, P.F., Lutz, J.A., Povak, N.A. | 2020 | Larson, A.J., Cansler, C.A., Kane, V.R., Churchill, D.J., Hessburg, P.F., Lutz, J.A., and Povak, N.A., 2020, Landscape evaluations and prescriptions for post-fire landscapes, Final Report: Joint Fire Science Program JFSP PROJECT ID—16-1-05-24, 56 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JO%3AT0%20%20%0A. |
Influence of past wildfires on wildfire effects in northern Rockies mixed-conifer forest, Final Report | Larson, A. J., Belote, R. T. | 2018 | Larson, A.J., and Belote, R.T., 2018, Influence of past wildfires on wildfire effects in northern Rockies mixed-conifer forest, Final Report: Joint Fire Science Program, JFSP PROJECT ID—14-1-02-9, 50 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%234V%40%20%20%0A. |
Cascading effects of climate change and wildfire on a subarctic lake—A 20?year case study of watershed change | A. S. Larsen, D. L. Rupp, D. K. Swanson, K. R. Hill | 2023 | Larsen, A.S., Rupp, D.L., Swanson, D.K., and Hill, K.R., 2023, Cascading effects of climate change and wildfire on a subarctic lake—A 20?year case study of watershed change: Ecosphere, v. 14, no. 7, article e4558, at https://doi.org/10.1002/ecs2.4558. |
Wildland fire emissions, carbon, and climate—U.S. emissions inventories | N. K. Larkin, S. M. Raffuse, T. M. Strand | 2014 | Larkin, N.K., Raffuse, S.M., and Strand, T.M., 2014, Wildland fire emissions, carbon, and climate—U.S. emissions inventories: Forest Ecology and Management, v. 317, p. 61–69, at https://doi.org/10.1016/j.foreco.2013.09.012. |
The Comprehensive Fire Information Reconciled Emissions (CFIRE) Inventory—Wildland fire emissions developed for the 2011 and 2014 U.S. National Emissions Inventory | N. K. Larkin, S. M. Raffuse, S. Huang, N. Pavlovic, P. Lahm, V. Rao | 2020 | Larkin, N.K., Raffuse, S.M., Huang, S., Pavlovic, N., Lahm, P., and Rao, V., 2020, The Comprehensive Fire Information Reconciled Emissions (CFIRE) Inventory—Wildland fire emissions developed for the 2011 and 2014 U.S. National Emissions Inventory: Journal of the Air & Waste Management Association, v. 70, no. 11, p. 1165–1185 at https://doi.org/10.1080/10962247.2020.1802365. |
Recent warming reverses forty-year decline in catastrophic lake drainage and hastens gradual lake drainage across northern Alaska | M. J. Lara, Y. Chen, B. M. Jones | 2021 | Lara, M.J., Chen, Y., and Jones, B.M., 2021, Recent warming reverses forty-year decline in catastrophic lake drainage and hastens gradual lake drainage across northern Alaska: Environmental Research Letters, v. 16, article 124019, at https://doi.org/10.1088/1748-9326/ac3602. |
Defining extreme wildland fires using geospatial and ancillary metrics | K. O. Lannom, W. T. Tinkham, A. M. S. Smith, J. Abatzoglou, B. A. Newingham, T. E. Hall, P. Morgan, E. K. Strand, T. B. Paveglio, J. W. Anderson, A. M. Sparks | 2014 | Lannom, K.O., Tinkham, W.T., Smith, A.M.S., Abatzoglou, J., Newingham, B.A., Hall, T.E., Morgan, P., Strand, E.K., Paveglio, T.B., et al., 2014, Defining extreme wildland fires using geospatial and ancillary metrics: International Journal of Wildland Fire, v. 23, no. 3, p. 322–337, at https://doi.org/10.1071/WF13065. |
Wildfire mapping in interior Alaska using deep neural networks on imbalanced datasets | Langford, Z., Kumar, J., Hoffman, F. | 2019 | Langford, Z., Kumar, J., and Hoffman, F., 2019, Wildfire mapping in interior Alaska using deep neural networks on imbalanced datasets, in 18th IEEE International Conference on Data Mining Workshops, ICDMW 2018, Singapore, 7–20 November 2018, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 770–778, at https://doi.org/10.1109/ICDMW.2018.00116. |
The impact of the 2016 Fort McMurray Horse River Wildfire on ambient air pollution levels in the Athabasca Oil Sands Region, Alberta, Canada | M. S. Landis, E. S. Edgerton, E. M. White, G. R. Wentworth, A. P. Sullivan, A. M. Dillner | 2018 | Landis, M.S., Edgerton, E.S., White, E.M., Wentworth, G.R., Sullivan, A.P., and Dillner, A.M., 2018, The impact of the 2016 Fort McMurray Horse River Wildfire on ambient air pollution levels in the Athabasca Oil Sands Region, Alberta, Canada: Science of the Total Environment, v. 618, p. 1665–1676, at https://doi.org/10.1016/j.scitotenv.2017.10.008. |
Relationships among burn severity, forest canopy structure and bat activity from spring burns in oak-hickory forests | M. J. Lacki, L. E. Dodd, N. S. Skowronski, M. B. Dickinson, L. K. Rieske | 2017 | Lacki, M.J., Dodd, L.E., Skowronski, N.S., Dickinson, M.B., and Rieske, L.K., 2017, Relationships among burn severity, forest canopy structure and bat activity from spring burns in oak-hickory forests: International Journal of Wildland Fire, v. 26, no. 11, p. 963–972, at https://doi.org/10.1071/Wf16159. |
Integrated modeling and assessment of North American forest carbon dynamics technical report—Tools for monitoring, reporting and projecting forest greenhouse gas emissions and removals | Kurz, W.A., Birdsey, R.A., Mascorro, V.S., Greenberg, D., Dai, Z., Olguin, M., Colditz, R. | 2016 | Kurz, W.A., Birdsey, R.A., Mascorro, V.S., Greenberg, D., Dai, Z., Olguin, M., and Colditz, R., 2016, Integrated modeling and assessment of North American forest carbon dynamics technical report—Tools for monitoring, reporting and projecting forest greenhouse gas emissions and removals: Montreal, Canada, Commission for Environmental Cooperation, 125 p., at https://www3.cec.org/islandora/en/item/11655-integrated-modeling-and-assessment-north-american-forest-carbon-dynamics. |
Remote sensing of forest burnt area, burn severity, and post-fire recovery—A review | E. Kurbanov, O. Vorobev, S. Lezhnin, J. Sha, J. Wang, X. Li, J. Cole, D. Dergunov, Y. Wang | 2022 | Kurbanov, E., Vorobev, O., Lezhnin, S., Sha, J., Wang, J., Li, X., Cole, J., Dergunov, D., and Wang, Y., 2022, Remote sensing of forest burnt area, burn severity, and post-fire recovery—A review: Remote Sensing, v. 14, no. 19, article 4714, at https://doi.org/10.3390/rs14194714. |
The Spatially Adaptable Filter for Error Reduction (SAFER) process—Remote sensing-based LANDFIRE disturbance mapping updates | S. S. Kumar, B. Tolk, R. Dittmeier, J. J. Picotte, I. La Puma, B. Peterson, T. D. Hatten | 2024 | Kumar, S.S., Tolk, B., Dittmeier, R., Picotte, J.J., La Puma, I., Peterson, B., and Hatten, T.D., 2024, The Spatially Adaptable Filter for Error Reduction (SAFER) process—Remote sensing-based LANDFIRE disturbance mapping updates: Fire, v. 7, no. 2, article 51, at https://doi.org/10.3390/fire7020051. |
Examining the existing definitions of wildland?urban interface for California | M. Kumar, S. Li, P. Nguyen, T. Banerjee | 2022 | Kumar, M., Li, S., Nguyen, P., and Banerjee, T., 2022, Examining the existing definitions of wildland?urban interface for California: Ecosphere, v. 13, no. 12, article e4306, at https://doi.org/10.1002/ecs2.4306. |
Scales of connectivity within stream temperature networks of the Clackamas River Basin, Oregon | M. Krochta, H. Chang | in press | Krochta, M., and Chang, H., in press, Scales of connectivity within stream temperature networks of the Clackamas River Basin, Oregon: Annals of the American Association of Geographers, at https://doi.org/10.1080/24694452.2023.2289981. |
Topographic and fire weather controls of fire refugia in forested ecosystems of northwestern North America | M. A. Krawchuk, S. L. Haire, J. Coop, M.-A. Parisien, E. Whitman, G. Chong, C. Miller | 2016 | Krawchuk, M.A., Haire, S.L., Coop, J., Parisien, M.-A., Whitman, E., Chong, G., and Miller, C., 2016, Topographic and fire weather controls of fire refugia in forested ecosystems of northwestern North America: Ecosphere, v. 7, no. 12, article e01632, at https://doi.org/10.1002/ecs2.1632. |
Evolving paradigms of aspen ecology and management—Impacts of stand condition and fire severity on vegetation dynamics | K. D. Krasnow, S. L. Stephens | 2015 | Krasnow, K.D., and Stephens, S.L., 2015, Evolving paradigms of aspen ecology and management—Impacts of stand condition and fire severity on vegetation dynamics: Ecosphere, v. 6, no. 1, article 12, at https://doi.org/10.1890/ES14-00354.1. |
Where wildfires destroy buildings in the US relative to the wildland-urban interface and national fire outreach programs | H. A. Kramer, M. H. Mockrin, P. M. Alexandre, S. I. Stewart, V. C. Radeloff | 2018 | Kramer, H.A., Mockrin, M.H., Alexandre, P.M., Stewart, S.I., and Radeloff, V.C., 2018, Where wildfires destroy buildings in the US relative to the wildland-urban interface and national fire outreach programs: International Journal of Wildland Fire, v. 27, no. 5, p. 329–341, at https://doi.org/10.1071/Wf17135. |
High wildfire damage in interface communities in California | H. A. Kramer, M. H. Mockrin, P. M. Alexandre, V. C. Radeloff | 2019 | Kramer, H.A., Mockrin, M.H., Alexandre, P.M., and Radeloff, V.C., 2019, High wildfire damage in interface communities in California: International Journal of Wildland Fire, v. 28, no. 9, p. 641–650, at https://doi.org/10.1071/Wf18108. |
Post-wildfire rebuilding and new development in California indicates minimal adaptation to fire risk | H. A. Kramer, V. Butsic, M. H. Mockrin, C. Ramirez-Reyes, P. M. Alexandre, V. C. Radeloff | 2021 | Kramer, H.A., Butsic, V., Mockrin, M.H., Ramirez-Reyes, C., Alexandre, P.M., and Radeloff, V.C., 2021, Post-wildfire rebuilding and new development in California indicates minimal adaptation to fire risk: Land Use Policy, v. 107, article 105502, at https://doi.org/10.1016/j.landusepol.2021.105502. |
California spotted owl habitat selection in a fire-managed landscape suggests conservation benefit of restoring historical fire regimes | A. Kramer, G. M. Jones, S. A. Whitmore, J. J. Keane, F. A. Atuo, B. P. Dotters, S. C. Sawyer, S. L. Stock, R. J. Gutierrez, M. Z. Peery | 2021 | Kramer, A., Jones, G.M., Whitmore, S.A., Keane, J.J., Atuo, F.A., Dotters, B.P., Sawyer, S.C., Stock, S.L., Gutierrez, R.J., and Peery, M.Z., 2021, California spotted owl habitat selection in a fire-managed landscape suggests conservation benefit of restoring historical fire regimes: Forest Ecology and Management, v. 479, article 118576, at https://doi.org/10.1016/j.foreco.2020.118576. |
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Contrasting geographic patterns of ignition probability and burn severity in the Mojave Desert | R. Klinger, E. C. Underwood, R. McKinley, M. L. Brooks | 2021 | Klinger, R., Underwood, E.C., McKinley, R., and Brooks, M.L., 2021, Contrasting geographic patterns of ignition probability and burn severity in the Mojave Desert: Frontiers in Ecology and Evolution, v. 9, article 593167, at https://doi.org/10.3389/fevo.2021.593167. |
An evaluation of remotely sensed indices for quantifying burn severity in arid ecoregions | R. Klinger, R. McKinley, M. Brooks | 2019 | Klinger, R., McKinley, R., and Brooks, M., 2019, An evaluation of remotely sensed indices for quantifying burn severity in arid ecoregions: International Journal of Wildland Fire, v. 28, no. 12, p. 951–968, at https://doi.org/10.1071/WF19025. |
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Applicability assessment of a spatiotemporal geostatistical fusion model for disaster monitoring—Two cases of flood and wildfire | Y. Kim | 2022 | Kim, Y., 2022, Applicability assessment of a spatiotemporal geostatistical fusion model for disaster monitoring—Two cases of flood and wildfire: Remote Sensing, v. 14, no. 24, article 6204, at https://doi.org/10.3390/rs14246204. |
Post-wildfire regeneration in a sky-island mixed- conifer ecosystem of the North American Great Basin | M. Kilpatrick, F. Biondi | 2020 | Kilpatrick, M., and Biondi, F., 2020, Post-wildfire regeneration in a sky-island mixed- conifer ecosystem of the North American Great Basin: Forests, v. 11, no. 9, article 900, at https://doi.org/10.3390/f11090900. |
Guadalupe Mountains National Park—Natural resource condition assessment | Kilkus, K., Nadeau, A.J., Amberg, S., Gardner, S., Komp, M.R., Drazkowski, B., Myers, M. | 2013 | Kilkus, K., Nadeau, A.J., Amberg, S., Gardner, S., Komp, M.R., Drazkowski, B., and Myers, M., 2013, Guadalupe Mountains National Park—Natural resource condition assessment: Fort Collins, Colo., U.S. National Park Service Natural Resource Report NPS/GUMO/NRR—2013/668, 328 p., at https://www.nps.gov/orgs/1439/nrca_gumo.htm. |
The need of monitoring forest fires through burned area mapping in Indonesia | R. Khoirunisa | 2021 | Khoirunisa, R., 2021, The need of monitoring forest fires through burned area mapping in Indonesia: Geographica—Science & Education Journal, v. 3, no. 1, p. 16–23, at https://usnsj.com/index.php/geographica/article/view/1423. |
Predicting increasing high severity area burned for three forested regions in the western United States using extreme value theory | A. R. Keyser, A. L. Westerling | 2019 | Keyser, A.R., and Westerling, A.L., 2019, Predicting increasing high severity area burned for three forested regions in the western United States using extreme value theory: Forest Ecology and Management, v. 432, p. 694–706, at https://doi.org/10.1016/j.foreco.2018.09.027. |
Simulated increases in fire activity reinforce shrub conversion in a southwestern US Forest | A. R. Keyser, D. J. Krofcheck, C. C. Remy, C. D. Allen, M. D. Hurteau | 2020 | Keyser, A.R., Krofcheck, D.J., Remy, C.C., Allen, C.D., and Hurteau, M.D., 2020, Simulated increases in fire activity reinforce shrub conversion in a southwestern US Forest: Ecosystems, v. 23, no. 8, p. 1702–1713, at https://doi.org/10.1007/s10021-020-00498-4. |
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The nativity and distribution of the cryptic invader Phalaris arundinacea (reed canarygrass) in riparian areas of the Columbia and Missouri river basins | K. M. Kettenring, D. R. Menuz, K. E. Mock | 2018 | Kettenring, K.M., Menuz, D.R., and Mock, K.E., 2018, The nativity and distribution of the cryptic invader Phalaris arundinacea (reed canarygrass) in riparian areas of the Columbia and Missouri river basins: Wetlands, v. 39, no. 1, p. 55–66, at https://doi.org/10.1007/s13157-018-1074-x. |
Differential response of native Arizona gray squirrels and introduced Abert's squirrels to a mosaic of burn severities | S. L. Ketcham, J. L. Koprowski, D. A. Falk | 2017 | Ketcham, S.L., Koprowski, J.L., and Falk, D.A., 2017, Differential response of native Arizona gray squirrels and introduced Abert's squirrels to a mosaic of burn severities: Mammal Study, v. 42, no. 4, p. 247–258, at https://doi.org/10.3106/041.042.0407. |
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Spatial and temporal patterns of forest disturbance and regrowth within the area of the Northwest Forest Plan | R. E. Kennedy, Z. Yang, W. B. Cohen, E. Pfaff, J. Braaten, P. Nelson | 2012 | Kennedy, R.E., Yang, Z., Cohen, W.B., Pfaff, E., Braaten, J., and Nelson, P., 2012, Spatial and temporal patterns of forest disturbance and regrowth within the area of the Northwest Forest Plan: Remote Sensing of Environment, v. 122, p. 117–133, at https://doi.org/10.1016/j.rse.2011.09.024. |
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Choose your neighborhood wisely—Implications of subsampling and autocorrelation structure in simultaneous autoregression models for landscape ecology | M. C. Kennedy, S. J. Prichard | 2017 | Kennedy, M.C., and Prichard, S.J., 2017, Choose your neighborhood wisely—Implications of subsampling and autocorrelation structure in simultaneous autoregression models for landscape ecology: Landscape Ecology, v. 32, no. 5, p. 945–952, at https://doi.org/10.1007/s10980-017-0499-6. |
Climate will increasingly determine post-fire tree regeneration success in low-elevation forests, Northern Rockies, USA | K. B. Kemp, P. E. Higuera, P. Morgan, J. T. Abatzoglou | 2019 | Kemp, K.B., Higuera, P.E., Morgan, P., and Abatzoglou, J.T., 2019, Climate will increasingly determine post-fire tree regeneration success in low-elevation forests, Northern Rockies, USA: Ecosphere, v. 10, no. 1, article e02568, at https://doi.org/10.1002/ecs2.2568. |
Fire legacies impact conifer regeneration across environmental gradients in the U.S. Northern Rockies | K. B. Kemp, P. E. Higuera, P. Morgan | 2015 | Kemp, K.B., Higuera, P.E., and Morgan, P., 2015, Fire legacies impact conifer regeneration across environmental gradients in the U.S. Northern Rockies: Landscape Ecology, v. 31, no. 3, p. 619–636, at https://doi.org/10.1007/s10980-015-0268-3. |
Prescribed burns as a tool to mitigate future wildfire smoke exposure—Lessons for states and rural environmental justice communities | M. M. Kelp, M. C. Carroll, T. Liu, R. M. Yantosca, H. E. Hockenberry, L. J. Mickley | 2023 | Kelp, M.M., Carroll, M.C., Liu, T., Yantosca, R.M., Hockenberry, H.E., and Mickley, L.J., 2023, Prescribed burns as a tool to mitigate future wildfire smoke exposure—Lessons for states and rural environmental justice communities: Earth's Future, v. 11, no. 6, article e2022EF003468, at https://doi.org/10.1029/2022ef003468. |
The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral | J. E. Keeley, T. J. Brennan, A. D. Syphard | 2022 | Keeley, J.E., Brennan, T.J., and Syphard, A.D., 2022, The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral: Ecosphere, v. 13, no. 8, article e4203, at https://doi.org/10.1002/ecs2.4203. |
The construction of probabilistic wildfire risk estimates for individual real estate parcels for the contiguous United States | E. J. Kearns, D. Saah, C. R. Levine, C. Lautenberger, O. M. Doherty, J. R. Porter, M. Amodeo, C. Rudeen, K. D. Woodward, G. W. Johnson, K. Markert, E. Shu, N. Freeman, M. Bauer, K. Lai, H. Hsieh, B. Wilson, B. McClenny, A. McMahon, F. Chishtie | 2022 | Kearns, E.J., Saah, D., Levine, C.R., Lautenberger, C., Doherty, O.M., Porter, J.R., Amodeo, M., Rudeen, C., Woodward, K.D., et al., 2022, The construction of probabilistic wildfire risk estimates for individual real estate parcels for the contiguous United States: Fire, v. 5, no. 4, article 117, at https://doi.org/10.3390/fire5040117. |
Assessing three fuel classification systems and their maps using Forest Inventory and Analysis (FIA) surface fuel measurements | Keane, R.E., Herynk, J.M., Toney, C., Urbanski, S.P., Lutes, D.C., Ottmar, R.D. | 2015 | Keane, R.E., Herynk, J.M., Toney, C., Urbanski, S.P., Lutes, D.C., and Ottmar, R.D., 2015, Assessing three fuel classification systems and their maps using Forest Inventory and Analysis (FIA) surface fuel measurements, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 128–140, at https://www.fs.usda.gov/research/treesearch/49435. |
Evaluating the performance and mapping of three fuel classification systems using Forest Inventory and Analysis surface fuel measurements | R. E. Keane, J. M. Herynk, C. Toney, S. P. Urbanski, D. C. Lutes, R. D. Ottmar | 2013 | Keane, R.E., Herynk, J.M., Toney, C., Urbanski, S.P., Lutes, D.C., and Ottmar, R.D., 2013, Evaluating the performance and mapping of three fuel classification systems using Forest Inventory and Analysis surface fuel measurements: Forest Ecology and Management, v. 305, p. 248–263, at https://doi.org/10.1016/j.foreco.2013.06.001. |
Forecasting the frequency and magnitude of postfire debris flows across southern California | J. W. Kean, D. M. Staley | 2021 | Kean, J.W., and Staley, D.M., 2021, Forecasting the frequency and magnitude of postfire debris flows across southern California: Earth's Future, v. 9, no. 3, article e2020EF001735, at https://doi.org/10.1029/2020ef001735. |
Quantifying burned area for North American forests—Implications for direct reduction of carbon stocks | E. S. Kasischke, T. Loboda, L. Giglio, N. H. F. French, E. E. Hoy, B. De Jong, D. Riano | 2011 | Kasischke, E.S., Loboda, T., Giglio, L., French, N.H.F., Hoy, E.E., De Jong, B., and Riano, D., 2011, Quantifying burned area for North American forests—Implications for direct reduction of carbon stocks: Journal of Geophysical Research—Biogeosciences, v. 116, no. 4, article G04003, at https://doi.org/10.1029/2011JG001707. |
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Integrating satellite imagery with simulation modeling to improve burn severity mapping | E. C. Karau, P. G. Sikkink, R. E. Keane, G. K. Dillon | 2014 | Karau, E.C., Sikkink, P.G., Keane, R.E., and Dillon, G.K., 2014, Integrating satellite imagery with simulation modeling to improve burn severity mapping: Environmental Management, v. 54, no. 1, p. 98–111, at https://doi.org/10.1007/s00267-014-0279-x. |
Assessing fire effects on forest spatial structure using a fusion of Landsat and airborne LiDAR data in Yosemite National Park | V. R. Kane, M. P. North, J. A. Lutz, D. J. Churchill, S. L. Roberts, D. F. Smith, R. J. McGaughey, J. T. Kane, M. L. Brooks | 2014 | Kane, V.R., North, M.P., Lutz, J.A., Churchill, D.J., Roberts, S.L., Smith, D.F., McGaughey, R.J., Kane, J.T., and Brooks, M.L., 2014, Assessing fire effects on forest spatial structure using a fusion of Landsat and airborne LiDAR data in Yosemite National Park: Remote Sensing of Environment, v. 151, p. 89–101, at https://doi.org/10.1016/j.rse.2013.07.041. |
Landscape-scale effects of fire severity on mixed-conifer and red fir forest structure in Yosemite National Park | V. R. Kane, J. A. Lutz, S. L. Roberts, D. F. Smith, R. J. McGaughey, N. A. Povak, M. L. Brooks | 2013 | Kane, V.R., Lutz, J.A., Roberts, S.L., Smith, D.F., McGaughey, R.J., Povak, N.A., and Brooks, M.L., 2013, Landscape-scale effects of fire severity on mixed-conifer and red fir forest structure in Yosemite National Park: Forest Ecology and Management, v. 287, p. 17–31, at https://doi.org/10.1016/j.foreco.2012.08.044. |
Water balance and topography predict fire and forest structure patterns | V. R. Kane, J. A. Lutz, C. Alina Cansler, N. A. Povak, D. J. Churchill, D. F. Smith, J. T. Kane, M. P. North | 2015 | Kane, V.R., Lutz, J.A., Alina Cansler, C., Povak, N.A., Churchill, D.J., Smith, D.F., Kane, J.T., and North, M.P., 2015, Water balance and topography predict fire and forest structure patterns: Forest Ecology and Management, v. 338, p. 1–13, at https://doi.org/10.1016/j.foreco.2014.10.038. |
Mixed severity fire effects within the Rim fire—Relative importance of local climate, fire weather, topography, and forest structure | V. R. Kane, C. A. Cansler, N. A. Povak, J. T. Kane, R. J. McGaughey, J. A. Lutz, D. J. Churchill, M. P. North | 2015 | Kane, V.R., Cansler, C.A., Povak, N.A., Kane, J.T., McGaughey, R.J., Lutz, J.A., Churchill, D.J., and North, M.P., 2015, Mixed severity fire effects within the Rim fire—Relative importance of local climate, fire weather, topography, and forest structure: Forest Ecology and Management, v. 358, p. 62–79, at https://doi.org/10.1016/j.foreco.2015.09.001. |
First-entry wildfires can create opening and tree clump patterns characteristic of resilient forests | V. R. Kane, B. N. Bartl-Geller, M. P. North, J. T. Kane, J. M. Lydersen, S. M. A. Jeronimo, B. M. Collins, L. Monika Moskal | 2019 | Kane, V.R., Bartl-Geller, B.N., North, M.P., Kane, J.T., Lydersen, J.M., Jeronimo, S.M.A., Collins, B.M., and Monika Moskal, L., 2019, First-entry wildfires can create opening and tree clump patterns characteristic of resilient forests: Forest Ecology and Management, v. 454, article 117659, at https://doi.org/10.1016/j.foreco.2019.117659. |
Advancing post-fire tree mortality models to limit fire-induced oak mortality, Final Report | Kane, J.M., Jones, A.M. | 2021 | Kane, J.M., and Jones, A.M., 2021, Advancing post-fire tree mortality models to limit fire-induced oak mortality, Final Report Joint Fire Science Program JFSP PROJECT ID—20-1-01-10, 28 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2B4W0%20%20%0A. |
Increasing wildfire impacts on snowpack in the western U.S. | S. K. Kampf, D. McGrath, M. G. Sears, S. R. Fassnacht, L. Kiewiet, J. C. Hammond | 2022 | Kampf, S.K., McGrath, D., Sears, M.G., Fassnacht, S.R., Kiewiet, L., and Hammond, J.C., 2022, Increasing wildfire impacts on snowpack in the western U.S.: Proceedings of the National Academy of Sciences, v. 119, no. 39, article e2200333119, at https://doi.org/10.1073/pnas.2200333119. |
PEMIP—Post-fire erosion model inter-comparison project | S. K. Kampf, B. M. Gannon, C. Wilson, F. Saavedra, M. E. Miller, A. Heldmyer, B. Livneh, P. Nelson, L. MacDonald | 2020 | Kampf, S.K., Gannon, B.M., Wilson, C., Saavedra, F., Miller, M.E., Heldmyer, A., Livneh, B., Nelson, P., and MacDonald, L., 2020, PEMIP—Post-fire erosion model inter-comparison project: Journal of Environmental Management, v. 268, article 110704, at https://doi.org/10.1016/j.jenvman.2020.110704. |
Pathways framework identifies wildfire impacts on agriculture | L. Kabeshita, L. L. Sloat, E. V. Fischer, S. Kampf, S. Magzamen, C. Schultz, M. J. Wilkins, E. Kinnebrew, N. D. Mueller | 2023 | Kabeshita, L., Sloat, L.L., Fischer, E.V., Kampf, S., Magzamen, S., Schultz, C., Wilkins, M.J., Kinnebrew, E., and Mueller, N.D., 2023, Pathways framework identifies wildfire impacts on agriculture: Nature Food, v. 4, p. 664–672, at https://doi.org/10.1038/s43016-023-00803-z. |
Evaluation of spectral indices for mapping burned areas using unsupervised classification in different ecosystems using spectral indices from Sentinel-2 images | J. A. da Silva Júnior, A. da Penha Pacheco | 2023 | da Silva Júnior, J.A., and da Penha Pacheco, A., 2023, Evaluation of spectral indices for mapping burned areas using unsupervised classification in different ecosystems using spectral indices from Sentinel-2 images: Revista Brasileira de Cartografia, v. 75, at https://doi.org/10.14393/RBCV75N0A-68307. |
Wildfire impacts on the persistent suspended sediment dynamics of the Ventura River, California | N. Jumps, A. B. Gray, J. J. Guilinger, W. C. Cowger | 2022 | Jumps, N., Gray, A.B., Guilinger, J.J., and Cowger, W.C., 2022, Wildfire impacts on the persistent suspended sediment dynamics of the Ventura River, California: Journal of Hydrology—Regional Studies, v. 41, article 101096, at https://doi.org/10.1016/j.ejrh.2022.101096. |
Rapid growth of large forest fires drives the exponential response of annual forest?fire area to aridity in the western United States | C. S. Juang, A. P. Williams, J. T. Abatzoglou, J. K. Balch, M. D. Hurteau, M. A. Moritz | 2022 | Juang, C.S., Williams, A.P., Abatzoglou, J.T., Balch, J.K., Hurteau, M.D., and Moritz, M.A., 2022, Rapid growth of large forest fires drives the exponential response of annual forest?fire area to aridity in the western United States: Geophysical Research Letters, v. 49, no. 5, article e2021GL097131, at https://doi.org/10.1029/2021gl097131. |
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Beyond inventories—Emergence of a new era in rangeland monitoring | M. O. Jones, D. E. Naugle, D. Twidwell, D. R. Uden, J. D. Maestas, B. W. Allred | 2020 | Jones, M.O., Naugle, D.E., Twidwell, D., Uden, D.R., Maestas, J.D., and Allred, B.W., 2020, Beyond inventories—Emergence of a new era in rangeland monitoring: Rangeland Ecology & Management, v. 73, no. 5, p. 577–583, at https://doi.org/10.1016/j.rama.2020.06.009. |
Satellite microwave detection of boreal forest recovery from the extreme 2004 wildfires in Alaska and Canada | M. O. Jones, J. S. Kimball, L. A. Jones | 2013 | Jones, M.O., Kimball, J.S., and Jones, L.A., 2013, Satellite microwave detection of boreal forest recovery from the extreme 2004 wildfires in Alaska and Canada: Global Change Biology, v. 19, no. 10, p. 3111–3122, at https://doi.org/10.1111/gcb.12288. |
Mapping wildfire jurisdictional complexity reveals opportunities for regional co-management | K. Jones, J. Vukomanovic, B. Nowell, S. McGovern | 2024 | Jones, K., Vukomanovic, J., Nowell, B., and McGovern, S., 2024, Mapping wildfire jurisdictional complexity reveals opportunities for regional co-management: Global Environmental Change, v. 84, article 102804, at https://doi.org/10.1016/j.gloenvcha.2024.102804. |
The American West as a social-ecological region—Drivers, dynamics and implications for nested social-ecological systems | K. Jones, J. Abrams, R. T. Belote, B. J. Beltran, J. Brandt, N. Carter, A. J. Castro, B. C. Chaffin, A. L. Metcalf, G. Roesch-McNally, K. E. Wallen, M. A. Williamson | 2019 | Jones, K., Abrams, J., Belote, R.T., Beltran, B.J., Brandt, J., Carter, N., Castro, A.J., Chaffin, B.C., Metcalf, A.L., et al., 2019, The American West as a social-ecological region—Drivers, dynamics and implications for nested social-ecological systems: Environmental Research Letters, v. 14, no. 11, article 115008, at https://doi.org/10.1088/1748-9326/ab4562. |
Spatial and temporal dynamics of Mexican spotted owl habitat in the southwestern US | G. M. Jones, A. J. Shirk, Z. Yang, R. J. Davis, J. L. Ganey, R. J. Gutiérrez, S. P. Healey, S. J. Hedwall, S. J. Hoagland, R. Maes, K. Malcolm, K. S. McKelvey, J. S. Sanderlin, M. K. Schwartz, M. E. Seamans, H. Y. Wan, S. A. Cushman | 2023 | Jones, G.M., Shirk, A.J., Yang, Z., Davis, R.J., Ganey, J.L., Gutiérrez, R.J., Healey, S.P., Hedwall, S.J., Hoagland, S.J., et al., 2023, Spatial and temporal dynamics of Mexican spotted owl habitat in the southwestern US: Landscape Ecology, v. 38, p. 23–37, at https://doi.org/10.1007/s10980-022-01418-8. |
Habitat selection by spotted owls after a megafire reflects their adaptation to historical frequent-fire regimes | G. M. Jones, H. A. Kramer, S. A. Whitmore, W. J. Berigan, D. J. Tempel, C. M. Wood, B. K. Hobart, T. Erker, F. A. Atuo, N. F. Pietrunti, R. Kelsey, R. J. Gutiérrez, M. Z. Peery | 2020 | Jones, G.M., Kramer, H.A., Whitmore, S.A., Berigan, W.J., Tempel, D.J., Wood, C.M., Hobart, B.K., Erker, T., Atuo, F.A., et al., 2020, Habitat selection by spotted owls after a megafire reflects their adaptation to historical frequent-fire regimes: Landscape Ecology, v. 35, no. 5, p. 1199–1213, at https://doi.org/10.1007/s10980-020-01010-y. |
Megafire causes persistent loss of an old?forest species | G. M. Jones, H. A. Kramer, W. J. Berigan, S. A. Whitmore, R. J. Gutiérrez, M. Z. Peery | 2021 | Jones, G.M., Kramer, H.A., Berigan, W.J., Whitmore, S.A., Gutiérrez, R.J., and Peery, M.Z., 2021, Megafire causes persistent loss of an old?forest species: Animal Conservation, v. 24, no. 6, p. 925–936, at https://doi.org/10.1111/acv.12697. |
Extreme wildfire supersedes long-term fuel treatment influences on fuel and vegetation in chaparral ecosystems of northern California, USA | A. M. Jones, J. M. Kane, E. A. Engber, C. A. Martorano, J. Gibson | 2023 | Jones, A.M., Kane, J.M., Engber, E.A., Martorano, C.A., and Gibson, J., 2023, Extreme wildfire supersedes long-term fuel treatment influences on fuel and vegetation in chaparral ecosystems of northern California, USA: Fire Ecology, v. 19, no. 1, article 28, at https://doi.org/10.1186/s42408-023-00186-3. |
Severe Fire Danger Index—A forecastable metric to inform firefighter and community wildfire risk management | W. M. Jolly, P. H. Freeborn, W. G. Page, B. W. Butler | 2019 | Jolly, W.M., Freeborn, P.H., Page, W.G., and Butler, B.W., 2019, Severe Fire Danger Index—A forecastable metric to inform firefighter and community wildfire risk management: Fire, v. 2, no. 3, article 47, at https://doi.org/10.3390/fire2030047. |
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Does conserving roadless wildland increase wildfire activity in western US national forests? | J. D. Johnston, J. B. Kilbride, G. W. Meigs, C. J. Dunn, R. E. Kennedy | 2021 | Johnston, J.D., Kilbride, J.B., Meigs, G.W., Dunn, C.J., and Kennedy, R.E., 2021, Does conserving roadless wildland increase wildfire activity in western US national forests?: Environmental Research Letters, v. 16, no. 8, article 084040, at https://doi.org/10.1088/1748-9326/ac13ee. |
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A land cover change detection and classification protocol for updating Alaska NLCD 2001 to 2011 | S. Jin, L. Yang, Z. Zhu, C. Homer | 2017 | Jin, S., Yang, L., Zhu, Z., and Homer, C., 2017, A land cover change detection and classification protocol for updating Alaska NLCD 2001 to 2011: Remote Sensing of Environment, v. 195, p. 44–55, at https://doi.org/10.1016/j.rse.2017.04.021. |
Wildfires correlate with reductions in aboveground tree carbon stocks and sequestration capacity on forest land in the western United States | P. Jiang, M. B. Russell, L. Frelich, C. Babcock, J. E. Smith | 2023 | Jiang, P., Russell, M.B., Frelich, L., Babcock, C., and Smith, J.E., 2023, Wildfires correlate with reductions in aboveground tree carbon stocks and sequestration capacity on forest land in the western United States: Science of the Total Environment, v. 893, article 164832, at https://doi.org/10.1016/j.scitotenv.2023.164832. |
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Estimating aboveground biomass in interior Alaska with Landsat data and field measurements | L. Ji, B. K. Wylie, D. R. Nossov, B. Peterson, M. P. Waldrop, J. W. McFarland, J. Rover, T. N. Hollingsworth | 2012 | Ji, L., Wylie, B.K., Nossov, D.R., Peterson, B., Waldrop, M.P., McFarland, J.W., Rover, J., and Hollingsworth, T.N., 2012, Estimating aboveground biomass in interior Alaska with Landsat data and field measurements: International Journal of Applied Earth Observation and Geoinformation, v. 18, p. 451–461, at https://doi.org/10.1016/j.jag.2012.03.019. |
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Temporal greenness trends in stable natural land cover and relationships with climatic variability across the conterminous United States | L. Ji, J. F. Brown | 2022 | Ji, L., and Brown, J.F., 2022, Temporal greenness trends in stable natural land cover and relationships with climatic variability across the conterminous United States: Earth Interactions, v. 26, no. 1, p. 66–83, at https://doi.org/10.1175/ei-d-21-0018.1. |
Forest structure and pattern vary by climate and landform across active-fire landscapes in the montane Sierra Nevada | S. M. A. Jeronimo, V. R. Kane, D. J. Churchill, J. A. Lutz, M. P. North, G. P. Asner, J. F. Franklin | 2019 | Jeronimo, S.M.A., Kane, V.R., Churchill, D.J., Lutz, J.A., North, M.P., Asner, G.P., and Franklin, J.F., 2019, Forest structure and pattern vary by climate and landform across active-fire landscapes in the montane Sierra Nevada: Forest Ecology and Management, v. 437, p. 70–86, at https://doi.org/10.1016/j.foreco.2019.01.033. |
Testing Huston's dynamic equilibrium model along fire and forest productivity gradients using avian monitoring data | W. M. Janousek, V. J. Dreitz | 2020 | Janousek, W.M., and Dreitz, V.J., 2020, Testing Huston's dynamic equilibrium model along fire and forest productivity gradients using avian monitoring data: Diversity and Distributions, v. 26, no. 12, p. 1715–1726, at https://doi.org/10.1111/ddi.13164. |
Wildfire in Utah—The physical and economic consequences of wildfire | Jakus, P.M, Kim, M.-K., Margin, R.C., Hammond, I., Hammill, E., Mesner, N. | 2017 | Jakus, P.M., Kim, M.-K., Margin, R.C., Hammond, I., Hammill, E., and Mesner, N., 2017, Wildfire in Utah—The physical and economic consequences of wildfire: Logan, Utah, Utah State University, Watershed Sciences Faculty Publications, Paper 1002, 200 p., at https://digitalcommons.usu.edu/wats_facpub/1002. |
Biophysical settings that influenced plantation survival during the 2015 wildfires in northern Rocky Mountain moist mixed-conifer forests | T. B. Jain, A. S. Nelson, B. C. Bright, J. C. Byrne, A. T. Hudak | 2021 | Jain, T.B., Nelson, A.S., Bright, B.C., Byrne, J.C., and Hudak, A.T., 2021, Biophysical settings that influenced plantation survival during the 2015 wildfires in northern Rocky Mountain moist mixed-conifer forests: Journal of Forestry, v. 120, no. 1, p. 22–36, at https://doi.org/10.1093/jofore/fvab036. |
The relationship between the polar jet stream and extreme wildfire events in North America | P. Jain, M. Flannigan | 2021 | Jain, P., and Flannigan, M., 2021, The relationship between the polar jet stream and extreme wildfire events in North America: Journal of Climate, v. 34, no. 15, p. 6247–6265, at https://doi.org/10.1175/jcli-d-20-0863.1. |
An unexpected decline in spring atmospheric humidity in the interior southwestern United States and implications for forest fires | T. W. P. Jacobson, R. Seager, A. P. Williams, I. R. Simpson, K. A. McKinnon, H. Liu | 2024 | Jacobson, T.W.P., Seager, R., Williams, A.P., Simpson, I.R., McKinnon, K.A., and Liu, H., 2024, An unexpected decline in spring atmospheric humidity in the interior southwestern United States and implications for forest fires: Journal of Hydrometeorology, v. 25, no. 3, p. 373–390, at https://doi.org/10.1175/jhm-d-23-0121.1. |
Climate dynamics preceding summer forest fires in California and the extreme case of 2018 | T. W. P. Jacobson, R. Seager, A. P. Williams, N. Henderson | 2022 | Jacobson, T.W.P., Seager, R., Williams, A.P., and Henderson, N., 2022, Climate dynamics preceding summer forest fires in California and the extreme case of 2018: Journal of Applied Meteorology and Climatology, v. 61, no. 8, p. 989–1002, at https://doi.org/10.1175/JAMC-D-21-0198.1. |
Comparing social constructions of wildfire risk across media, government, and participatory discourse in a Colorado fireshed | M. Jacobson, H. Smith, H. R. Huber-Stearns, E. J. Davis, A. S. Cheng, A. Deak | 2022 | Jacobson, M., Smith, H., Huber-Stearns, H.R., Davis, E.J., Cheng, A.S., and Deak, A., 2022, Comparing social constructions of wildfire risk across media, government, and participatory discourse in a Colorado fireshed: Journal of Risk Research, v. 25, no. 6, p. 697–714, at https://doi.org/10.1080/13669877.2021.1962954. |
Climate, fire regime, geomorphology, and conspecifics influence the spatial distribution of Chinook Salmon Redds | G. R. Jacobs, R. F. Thurow, J. M. Buffington, D. J. Isaak, S. J. Wenger | 2021 | Jacobs, G.R., Thurow, R.F., Buffington, J.M., Isaak, D.J., and Wenger, S.J., 2021, Climate, fire regime, geomorphology, and conspecifics influence the spatial distribution of Chinook Salmon Redds: Transactions of the American Fisheries Society, v. 150, no. 1, p. 8–23, at https://doi.org/10.1002/tafs.10270. |
Comparing geography and severity of managed wildfires in California and the southwest USA before and after the implementation of the 2009 Policy Guidance | J. M. Iniguez, A. M. Evans, S. Dadashi, J. D. Young, M. D. Meyer, A. E. Thode, S. J. Hedwall, S. M. McCaffrey, S. D. Fillmore, R. Bean | 2022 | Iniguez, J.M., Evans, A.M., Dadashi, S., Young, J.D., Meyer, M.D., Thode, A.E., Hedwall, S.J., McCaffrey, S.M., Fillmore, S.D., and Bean, R., 2022, Comparing geography and severity of managed wildfires in California and the southwest USA before and after the implementation of the 2009 Policy Guidance: Forests, v. 13, no. 5, article 793, at https://doi.org/10.3390/f13050793. |
Effects of changing wildfire management strategies, Final Report | Iniguez, J., Thode, A., McCaffrey, S., Evans, A., Meyer, M., Hedwall, S. | 2021 | Iniguez, J., Thode, A., McCaffrey, S., Evans, A., Meyer, M., and Hedwall, S., 2021, Effects of changing wildfire management strategies, Final Report: Joint Fire Science Program JFSP PROJECT ID—17-01-03, 42 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JK4V%40%20%20%0A. |
Viewscape change highlights shifting drivers of exurban development over time | N. C. Inglis, J. Vukomanovic, A. Petrasova, R. K. Meentemeyer | 2023 | Inglis, N.C., Vukomanovic, J., Petrasova, A., and Meentemeyer, R.K., 2023, Viewscape change highlights shifting drivers of exurban development over time: Landscape and Urban Planning, v. 238, article 104833, at https://doi.org/10.1016/j.landurbplan.2023.104833. |
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Comparing modeled emissions from wildfire and prescribed burning of post-thinning fuel—A case study of the 2016 Pioneer Fire | J. Hyde, E. K. Strand | 2019 | Hyde, J., and Strand, E.K., 2019, Comparing modeled emissions from wildfire and prescribed burning of post-thinning fuel—A case study of the 2016 Pioneer Fire: Fire, v. 2, no. 2, article 22, at https://doi.org/10.3390/fire2020022. |
Seeing the disturbed forest for the trees—Remote sensing is underutilized to quantify critical zone response to unprecedented disturbance | K. Hwang, A. A. Harpold, C. L. Tague, L. Lowman, G. F. S. Boisramé, K. B. Lininger, P. L. Sullivan, A. Manning, L. Graup, M. Litvak, G. Lewis, K. Miller, P. D. Brooks, H. R. Barnard | 2023 | Hwang, K., Harpold, A.A., Tague, C.L., Lowman, L., Boisramé, G.F.S., Lininger, K.B., Sullivan, P.L., Manning, A., Graup, L., et al., 2023, Seeing the disturbed forest for the trees—Remote sensing is underutilized to quantify critical zone response to unprecedented disturbance: Earth's Future, v. 11, no. 8, article e2022EF003314, at https://doi.org/10.1029/2022EF003314. |
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Assessing the shape accuracy of coarse resolution burned area identifications | M. L. Humber, L. Boschetti, L. Giglio | 2020 | Humber, M.L., Boschetti, L., and Giglio, L., 2020, Assessing the shape accuracy of coarse resolution burned area identifications: IEEE Transactions on Geoscience and Remote Sensing, v. 58, no. 3, p. 1516–1526, at https://doi.org/10.1109/tgrs.2019.2943901. |
A remote sensing-based approach to estimating the fire spread rate parameter for individual burn patch extraction | M. Humber, M. Zubkova, L. Giglio | 2022 | Humber, M., Zubkova, M., and Giglio, L., 2022, A remote sensing-based approach to estimating the fire spread rate parameter for individual burn patch extraction: International Journal of Remote Sensing, v. 43, no. 2, p. 649–673, at https://doi.org/10.1080/01431161.2022.2027544. |
Efficacy of resource objective wildfires for restoration of ponderosa pine (Pinus ponderosa) forests in northern Arizona | D. W. Huffman, A. J. Sánchez Meador, M. T. Stoddard, J. E. Crouse, J. P. Roccaforte | 2017 | Huffman, D.W., Sánchez Meador, A.J., Stoddard, M.T., Crouse, J.E., and Roccaforte, J.P., 2017, Efficacy of resource objective wildfires for restoration of ponderosa pine (Pinus ponderosa) forests in northern Arizona: Forest Ecology and Management, v. 389, p. 395–403, at https://doi.org/10.1016/j.foreco.2016.12.036. |
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Charcoal reflectance suggests heating duration and fuel moisture affected burn severity in four Alaskan tundra wildfires | V. A. Hudspith, C. M. Belcher, J. Barnes, C. B. Dash, R. Kelly, F. S. Hu | 2017 | Hudspith, V.A., Belcher, C.M., Barnes, J., Dash, C.B., Kelly, R., and Hu, F.S., 2017, Charcoal reflectance suggests heating duration and fuel moisture affected burn severity in four Alaskan tundra wildfires: International Journal of Wildland Fire, v. 26, no. 4, p. 306–316, at https://doi.org/10.1071/Wf16177. |
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How vegetation recovery and fuel conditions in past fires influences fuels and future fire management in five western U.S. ecosystems, Final Report | Hudak, A. T., Newingham, B. A., Strand, E. K., Morgan, P. | 2018 | Hudak, A.T., Newingham, B.A., Strand, E.K., and Morgan, P., 2018, How vegetation recovery and fuel conditions in past fires influences fuels and future fire management in five western U.S. ecosystems, Final Report: Joint Fire Science Program JFSP PROJECT ID—14-1-02-27, 33 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%3F5W0%20%20%0A. |
Updating land cover automatically based on change detection using satellite images—Case study of national forests in southern California | S. L. Huang, C. Ramirez, K. Kennedy, J. Mallory, J. L. Wang, C. Chu | 2017 | Huang, S.L., Ramirez, C., Kennedy, K., Mallory, J., Wang, J.L., and Chu, C., 2017, Updating land cover automatically based on change detection using satellite images—Case study of national forests in southern California: GIScience & Remote Sensing, v. 54, no. 4, p. 495–514, at https://doi.org/10.1080/15481603.2017.1286727. |
Projecting the spatiotemporal carbon dynamics of the Greater Yellowstone Ecosystem from 2006 to 2050 | S. Huang, S. Liu, J. Liu, D. Dahal, C. Young, B. Davis, T. L. Sohl, T. J. Hawbaker, B. Sleeter, Z. Zhu | 2015 | Huang, S., Liu, S., Liu, J., Dahal, D., Young, C., Davis, B., Sohl, T.L., Hawbaker, T.J., Sleeter, B., and Zhu, Z., 2015, Projecting the spatiotemporal carbon dynamics of the Greater Yellowstone Ecosystem from 2006 to 2050: Carbon Balance and Management, v. 10, no. 1, article 7, at https://doi.org/10.1186/s13021-015-0017-6. |
Modeling spatially explicit fire impact on gross primary production in interior Alaska using satellite images coupled with eddy covariance | S. Huang, H. Liu, D. Dahal, S. Jin, L. R. Welp, J. Liu, S. Liu | 2013 | Huang, S., Liu, H., Dahal, D., Jin, S., Welp, L.R., Liu, J., and Liu, S., 2013, Modeling spatially explicit fire impact on gross primary production in interior Alaska using satellite images coupled with eddy covariance: Remote Sensing of Environment, v. 135, p. 178–188, at https://doi.org/10.1016/j.rse.2013.04.003. |
Reconstructing satellite images to quantify spatially explicit land surface change caused by fires and succession—A demonstration in the Yukon River Basin of interior Alaska | S. Huang, S. Jin, D. Dahal, X. Chen, C. Young, H. Liu, S. Liu | 2013 | Huang, S., Jin, S., Dahal, D., Chen, X., Young, C., Liu, H., and Liu, S., 2013, Reconstructing satellite images to quantify spatially explicit land surface change caused by fires and succession—A demonstration in the Yukon River Basin of interior Alaska: ISPRS Journal of Photogrammetry and Remote Sensing, v. 79, p. 94–105, at https://doi.org/10.1016/j.isprsjprs.2013.02.010. |
The economic value of selling carbon credits from restored forests—A case study from the Navajo nation's tribal forests | C. H. Huang, C. Sorensen | 2011 | Huang, C.H., and Sorensen, C., 2011, The economic value of selling carbon credits from restored forests—A case study from the Navajo nation's tribal forests: Western Journal of Applied Forestry, v. 26, no. 1, p. 37–45, at https://doi.org/10.1093/wjaf/26.1.37. |
Development of time series stacks of Landsat images for reconstructing forest disturbance history | C. Huang, S. N. Goward, J. G. Masek, F. Gao, E. F. Vermote, N. Thomas, K. Schleeweis, R. E. Kennedy, Z. Zhu, J. C. Eidenshink, J. R. G. Townshend | 2009 | Huang, C., Goward, S.N., Masek, J.G., Gao, F., Vermote, E.F., Thomas, N., Schleeweis, K., Kennedy, R.E., Zhu, Z., et al., 2009, Development of time series stacks of Landsat images for reconstructing forest disturbance history: International Journal of Digital Earth, v. 2, no. 3, p. 195–218, at https://doi.org/10.1080/17538940902801614. |
Large-scale burn severity mapping in multispectral imagery using deep semantic segmentation models | X. Hu, P. Zhang, Y. Ban | 2023 | Hu, X., Zhang, P., and Ban, Y., 2023, Large-scale burn severity mapping in multispectral imagery using deep semantic segmentation models: ISPRS Journal of Photogrammetry and Remote Sensing, v. 196, p. 228–240, at https://doi.org/10.1016/j.isprsjprs.2022.12.026. |
Comparing Sentinel-2 and Landsat 8 for burn severity mapping in western North America | A. A. Howe, S. A. Parks, B. J. Harvey, S. J. Saberi, J. A. Lutz, L. L. Yocom | 2022 | Howe, A.A., Parks, S.A., Harvey, B.J., Saberi, S.J., Lutz, J.A., and Yocom, L.L., 2022, Comparing Sentinel-2 and Landsat 8 for burn severity mapping in western North America: Remote Sensing, v. 14, no. 20, article 5249, at https://doi.org/10.3390/rs14205249. |
Utilizing multi-sensor fire detections to map fires in the United States | Howard, S. M., Picotte, J. J., Coan, M. J. | 2014 | Howard, S.M., Picotte, J.J., and Coan, M.J., 2014, Utilizing multi-sensor fire detections to map fires in the United States, in ISPRS Technical Commission I Symposium, Denver, Colo., 17–20 November 2014, ISPRS Archives XL-1: International Society for Photogrammetry and Remote Sensing, p. 161–166, at https://doi.org/10.5194/isprsarchives-XL-1-161-2014. |
Can Siberian alder N-fixation offset N-loss after severe fire? Quantifying post-fire Siberian alder distribution, growth, and N-fixation in boreal Alaska | B. Houseman, R. Ruess, T. Hollingsworth, D. Verbyla | 2020 | Houseman, B., Ruess, R., Hollingsworth, T., and Verbyla, D., 2020, Can Siberian alder N-fixation offset N-loss after severe fire? Quantifying post-fire Siberian alder distribution, growth, and N-fixation in boreal Alaska: PLoS ONE, v. 15, no. 9, article e0238004, at https://doi.org/10.1371/journal.pone.0238004. |
Interactive effects of wildfire, forest management, and isolation on amphibian and parasite abundance | B. R. Hossack, W. H. Lowe, R. K. Honeycutt, S. A. Parks, P. S. Corn | 2013 | Hossack, B.R., Lowe, W.H., Honeycutt, R.K., Parks, S.A., and Corn, P.S., 2013, Interactive effects of wildfire, forest management, and isolation on amphibian and parasite abundance: Ecological Applications, v. 23, no. 2, p. 479–492, at https://doi.org/10.1890/12-0316.1. |
Rapid increases and time-lagged declines in amphibian occupancy after wildfire | B. R. Hossack, W. H. Lowe, P. S. Corn | 2013 | Hossack, B.R., Lowe, W.H., and Corn, P.S., 2013, Rapid increases and time-lagged declines in amphibian occupancy after wildfire: Conservation Biology, v. 27, no. 1, p. 219–228, at https://doi.org/10.1111/j.1523-1739.2012.01921.x. |
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Germination response to temperature and moisture to predict distributions of the invasive grass red brome and wildfire | K. J. Horn, R. Nettles, S. B. St Clair | 2015 | Horn, K.J., Nettles, R., and St Clair, S.B., 2015, Germination response to temperature and moisture to predict distributions of the invasive grass red brome and wildfire: Biological Invasions, v. 17, no. 6, p. 1849–1857, at https://doi.org/10.1007/s10530-015-0841-3. |
Wildfire and exotic grass invasion alter plant productivity in response to climate variability in the Mojave Desert | K. J. Horn, S. B. St. Clair | 2016 | Horn, K.J., and St. Clair, S.B., 2016, Wildfire and exotic grass invasion alter plant productivity in response to climate variability in the Mojave Desert: Landscape Ecology, v. 32, no. 3, p. 635–646, at https://doi.org/10.1007/s10980-016-0466-7. |
Mortality reconsidered—Testing and extending models of fire-induced tree mortality across the US, Final Project Summary | Hood, S.M., Varner, J.M., Cansler, C.A. | 2019 | Hood, S.M., Varner, J.M., and Cansler, C.A., 2019, Mortality reconsidered—Testing and extending models of fire-induced tree mortality across the US, Final Project Summary: Joint Fire Science Program JFSP PROJECT ID—16-1-04-8, 40 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JO4WP%20%20%0A. |
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Predicting fire-mediated forest structure over biophysical gradients in moist mixed conifer forests, Final Report | Holz, A., Platt, L., Kemp, K. , Naficy, C. | 2021 | Holz, A., Platt, L., Kemp, K., and Naficy, C., 2021, Predicting fire-mediated forest structure over biophysical gradients in moist mixed conifer forests, Final Report: Joint Fire Science Program JFSP PROJECT ID—19-1-01-49, 33 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2B%3FT0%20%20%0A. |
Improved fire severity mapping in the North American boreal forest using a hybrid composite method | L. M. Holsinger, S. A. Parks, L. B. Saperstein, R. A. Loehman, E. Whitman, J. Barnes, M. A. Parisien | 2022 | Holsinger, L.M., Parks, S.A., Saperstein, L.B., Loehman, R.A., Whitman, E., Barnes, J., and Parisien, M.A., 2022, Improved fire severity mapping in the North American boreal forest using a hybrid composite method: Remote Sensing in Ecology and Conservation, v. 8, no. 2, p. 222–235, at https://doi.org/10.1002/rse2.238. |
Weather, fuels, and topography impede wildland fire spread in western US landscapes | L. Holsinger, S. A. Parks, C. Miller | 2016 | Holsinger, L., Parks, S.A., and Miller, C., 2016, Weather, fuels, and topography impede wildland fire spread in western US landscapes: Forest Ecology and Management, v. 380, p. 59–69, at https://doi.org/10.1016/j.foreco.2016.08.035. |
Wildfire probability estimated from recent climate and fine fuels across the big sagebrush region | M. C. Holdrege, D. R. Schlaepfer, K. A. Palmquist, M. Crist, K. E. Doherty, W. K. Lauenroth, T. E. Remington, K. Riley, K. C. Short, J. C. Tull, L. A. Wiechman, J. B. Bradford | 2024 | Holdrege, M.C., Schlaepfer, D.R., Palmquist, K.A., Crist, M., Doherty, K.E., Lauenroth, W.K., Remington, T.E., Riley, K., Short, K.C., et al., 2024, Wildfire probability estimated from recent climate and fine fuels across the big sagebrush region: Fire Ecology, v. 20, no. 1, article 22, at https://doi.org/10.1186/s42408-024-00252-4. |
Decreasing fire season precipitation increased recent western US forest wildfire activity | Z. A. Holden, A. Swanson, C. H. Luce, W. M. Jolly, M. Maneta, J. W. Oyler, D. A. Warren, R. Parsons, D. Affleck | 2018 | Holden, Z.A., Swanson, A., Luce, C.H., Jolly, W.M., Maneta, M., Oyler, J.W., Warren, D.A., Parsons, R., and Affleck, D., 2018, Decreasing fire season precipitation increased recent western US forest wildfire activity: Proceedings of the National Academy of Sciences of the United States of America, v. 115, no. 36, p. E8349–E8357, at https://doi.org/10.1073/pnas.1802316115. |
A predictive model of burn severity based on 20-year satellite-inferred burn severity data in a large southwestern US wilderness area | Z. A. Holden, P. Morgan, J. S. Evans | 2009 | Holden, Z.A., Morgan, P., and Evans, J.S., 2009, A predictive model of burn severity based on 20-year satellite-inferred burn severity data in a large southwestern US wilderness area: Forest Ecology and Management, v. 258, no. 11, p. 2399–2406, at https://doi.org/10.1016/j.foreco.2009.08.017. |
Wildfire extent and severity correlated with annual streamflow distribution and timing in the Pacific Northwest, USA (1984–2005) | Z. A. Holden, C. H. Luce, M. A. Crimmins, P. Morgan | 2012 | Holden, Z.A., Luce, C.H., Crimmins, M.A., and Morgan, P., 2012, Wildfire extent and severity correlated with annual streamflow distribution and timing in the Pacific Northwest, USA (1984–2005): Ecohydrology, v. 5, no. 5, p. 677–684, at https://doi.org/10.1002/eco.257. |
Fire severity influences the response of soil microbes to a boreal forest fire | S. R. Holden, B. M. Rogers, K. K. Treseder, J. T. Randerson | 2016 | Holden, S.R., Rogers, B.M., Treseder, K.K., and Randerson, J.T., 2016, Fire severity influences the response of soil microbes to a boreal forest fire: Environmental Research Letters, v. 11, no. 3, article 035004, at https://doi.org/10.1088/1748-9326/11/3/035004. |
Post-fire water quality—An investigation of determinants and recovery processes in burned watersheds across the western U.S., Final Report | Hogue, T.S., McCray, J. | 2019 | Hogue, T.S., and McCray, J., 2019, Post-fire water quality—An investigation of determinants and recovery processes in burned watersheds across the western U.S., Final Report: Joint Fire Science Program JFSP PROJECT ID—14-1-06-14, 47 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%234T0%20%20%0A. |
Changes in severity distribution after subsequent fires on the north rim of Grand Canyon National Park, Arizona, USA | V. Hoff, C. C. Teske, J. P. Riddering, L. P. Queen, E. G. Gdula, W. A. Bunn | 2014 | Hoff, V., Teske, C.C., Riddering, J.P., Queen, L.P., Gdula, E.G., and Bunn, W.A., 2014, Changes in severity distribution after subsequent fires on the north rim of Grand Canyon National Park, Arizona, USA: Fire Ecology, v. 10, no. 2, p. 48–63, at https://doi.org/10.4996/fireecology.1002048. |
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A short-interval reburn catalyzes departures from historical structure and composition in a mesic mixed-conifer forest | T. J. Hoecker, M. G. Turner | 2022 | Hoecker, T.J., and Turner, M.G., 2022, A short-interval reburn catalyzes departures from historical structure and composition in a mesic mixed-conifer forest: Forest Ecology and Management, v. 504, article 119814, at https://doi.org/10.1016/j.foreco.2021.119814. |
Widespread exposure to altered fire regimes under 2?°C warming is projected to transform conifer forests of the western United States | T. J. Hoecker, S. A. Parks, M. Krosby, S. Z. Dobrowski | 2023 | Hoecker, T.J., Parks, S.A., Krosby, M., and Dobrowski, S.Z., 2023, Widespread exposure to altered fire regimes under 2?°C warming is projected to transform conifer forests of the western United States: Communications Earth & Environment, v. 4, no. 1, article 295, at https://doi.org/10.1038/s43247-023-00954-8. |
Multitemporal LiDAR improves estimates of fire severity in forested landscapes | M. S. Hoe, C. J. Dunn, H. Temesgen | 2018 | Hoe, M.S., Dunn, C.J., and Temesgen, H., 2018, Multitemporal LiDAR improves estimates of fire severity in forested landscapes: International Journal of Wildland Fire, v. 27, no. 9, p. 581–594, at https://doi.org/10.1071/Wf17141. |
Stable isotopes reveal unexpected relationships between fire history and the diet of spotted owls | B. K. Hobart, H. A. Kramer, G. M. Jones, B. P. Dotters, S. A. Whitmore, J. J. Keane, M. Z. Peery | 2021 | Hobart, B.K., Kramer, H.A., Jones, G.M., Dotters, B.P., Whitmore, S.A., Keane, J.J., and Peery, M.Z., 2021, Stable isotopes reveal unexpected relationships between fire history and the diet of spotted owls: IBIS, v. 163, no. 1, p. 253–259, at https://doi.org/10.1111/ibi.12832. |
Hydrological and meteorological controls on large wildfire ignition and burned area in northern California during 2017–2020 | Y. Hiraga, M. L. Kavvas | 2021 | Hiraga, Y., and Kavvas, M.L., 2021, Hydrological and meteorological controls on large wildfire ignition and burned area in northern California during 2017–2020: Fire, v. 4, no. 4, article 90, at https://doi.org/10.3390/fire4040090. |
Rocky Mountain subalpine forests now burning more than any time in recent millennia | P. E. Higuera, B. N. Shuman, K. D. Wolf | 2021 | Higuera, P.E., Shuman, B.N., and Wolf, K.D., 2021, Rocky Mountain subalpine forests now burning more than any time in recent millennia: Proceedings of the National Academy of Sciences of the United States of America, v. 118, no. 25, article e2103135118, at https://doi.org/10.1073/pnas.2103135118. |
Shifting social-ecological fire regimes explain increasing structure loss from western wildfires | P. E. Higuera, M. C. Cook, J. K. Balch, E. N. Stavros, A. L. Mahood, L. A. St. Denis | 2023 | Higuera, P.E., Cook, M.C., Balch, J.K., Stavros, E.N., Mahood, A.L., and St. Denis, L.A., 2023, Shifting social-ecological fire regimes explain increasing structure loss from western wildfires: PNAS Nexus, v. 2, article pgad005, at https://doi.org/10.1093/pnasnexus/pgad005/7017542. |
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Carbon stocks of trees killed by bark beetles and wildfire in the western United States | J. A. Hicke, A. J. H. Meddens, C. D. Allen, C. A. Kolden | 2013 | Hicke, J.A., Meddens, A.J.H., Allen, C.D., and Kolden, C.A., 2013, Carbon stocks of trees killed by bark beetles and wildfire in the western United States: Environmental Research Letters, v. 8, no. 3, article 035032, at https://doi.org/10.1088/1748-9326/8/3/035032. |
Is burn severity related to fire intensity? Observations from landscape scale remote sensing | H. Heward, A. M. S. Smith, D. P. Roy, W. T. Tinkham, C. M. Hoffman, P. Morgan, K. O. Lannom | 2013 | Heward, H., Smith, A.M.S., Roy, D.P., Tinkham, W.T., Hoffman, C.M., Morgan, P., and Lannom, K.O., 2013, Is burn severity related to fire intensity? Observations from landscape scale remote sensing: International Journal of Wildland Fire, v. 22, no. 7, p. 910–918, at https://doi.org/10.1071/WF12087. |
Wildfire burn severity and stream chemistry influence aquatic invertebrate and riparian avian mercury exposure in forested ecosystems | G. Herring, L. B. Tennant, J. J. Willacker, M. Johnson, R. B. Siegel, J. S. Polasik, C. A. Eagles-Smith | 2024 | Herring, G., Tennant, L.B., Willacker, J.J., Johnson, M., Siegel, R.B., Polasik, J.S., and Eagles-Smith, C.A., 2024, Wildfire burn severity and stream chemistry influence aquatic invertebrate and riparian avian mercury exposure in forested ecosystems: Ecotoxicology, v. 33, p. 131–141, at https://doi.org/10.1007/s10646-024-02730-6. |
Assessing the effectiveness of green landscape buffers to reduce fire severity and limit fire spread in California—Case study of golf courses | C. Herbert, V. Butsic | 2022 | Herbert, C., and Butsic, V., 2022, Assessing the effectiveness of green landscape buffers to reduce fire severity and limit fire spread in California—Case study of golf courses: Fire, v. 5, no. 2, article 44, at https://doi.org/10.3390/fire5020044. |
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The effects of post-wildfire salvage logging on plant reproductive success and pollination in Symphoricarpos albus, a fire-tolerant shrub | L. J. Heil, L. A. Burkle | 2019 | Heil, L.J., and Burkle, L.A., 2019, The effects of post-wildfire salvage logging on plant reproductive success and pollination in Symphoricarpos albus, a fire-tolerant shrub: Forest Ecology and Management, v. 432, p. 157–163, at https://doi.org/10.1016/j.foreco.2018.09.013. |
Recent post-wildfire salvage logging benefits local and landscape floral and bee communities | L. J. Heil, L. A. Burkle | 2018 | Heil, L.J., and Burkle, L.A., 2018, Recent post-wildfire salvage logging benefits local and landscape floral and bee communities: Forest Ecology and Management, v. 424, p. 267–275, at https://doi.org/10.1016/j.foreco.2018.05.009. |
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MODIS-based smoke detection shows that daily smoke cover dampens fire severity in initial burns but not reburns in complex terrain | L. B. Harris, A. H. Taylor | 2022 | Harris, L.B., and Taylor, A.H., 2022, MODIS-based smoke detection shows that daily smoke cover dampens fire severity in initial burns but not reburns in complex terrain: International Journal of Wildland Fire, v. 31, no. 11, p. 1002–1013, at https://doi.org/10.1071/WF22061. |
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Accuracy of node and bud-scar counts for aging two dominant conifers in western North America | L. E. Hankin, P. E. Higuera, K. T. Davis, S. Z. Dobrowski | 2018 | Hankin, L.E., Higuera, P.E., Davis, K.T., and Dobrowski, S.Z., 2018, Accuracy of node and bud-scar counts for aging two dominant conifers in western North America: Forest Ecology and Management, v. 427, p. 365–371, at https://doi.org/10.1016/j.foreco.2018.06.001. |
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Proportion of forest area burned at high-severity increases with increasing forest cover and connectivity in western US watersheds | E. J. Francis, P. Pourmohammadi, Z. L. Steel, B. M. Collins, M. D. Hurteau | 2023 | Francis, E.J., Pourmohammadi, P., Steel, Z.L., Collins, B.M., and Hurteau, M.D., 2023, Proportion of forest area burned at high-severity increases with increasing forest cover and connectivity in western US watersheds: Landscape Ecology, v. 38, p. 2501–2518, at https://doi.org/10.1007/s10980-023-01710-1. |
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Changes in potential wildland fire suppression costs due to restoration treatments in northern Arizona ponderosa pine forests | R. A. Fitch, Y. S. Kim, A. E. M. Waltz, J. E. Crouse | 2018 | Fitch, R.A., Kim, Y.S., Waltz, A.E.M., and Crouse, J.E., 2018, Changes in potential wildland fire suppression costs due to restoration treatments in northern Arizona ponderosa pine forests: Forest Policy and Economics, v. 87, p. 101–114, at https://doi.org/10.1016/j.forpol.2017.11.006. |
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Fractional vegetation cover ratio estimated from radiative transfer modeling outperforms spectral indices to assess fire severity in several Mediterranean plant communities | J. M. Fernández-Guisuraga, L. Calvo, C. Quintano, A. Fernández-Manso, P. M. Fernandes | 2023 | Fernández-Guisuraga, J.M., Calvo, L., Quintano, C., Fernández-Manso, A., and Fernandes, P.M., 2023, Fractional vegetation cover ratio estimated from radiative transfer modeling outperforms spectral indices to assess fire severity in several Mediterranean plant communities: Remote Sensing of Environment, v. 290, article 113542, at https://doi.org/10.1016/j.rse.2023.113542. |
Estimates of fine fuel litter biomass in the northern Great Basin reveal increases during short fire-free intervals associated with invasive annual grasses | J. M. Fernandez-Guisuraga, L. Calvo, P. M. Fernandes, A. Hulet, B. Perryman, B. Schultz, K. S. Jensen, J. Enterkine, C. S. Boyd, K. W. Davies, D. D. Johnson, K. Wollstein, W. J. Price, S. A. Arispe | 2023 | Fernandez-Guisuraga, J.M., Calvo, L., Fernandes, P.M., Hulet, A., Perryman, B., Schultz, B., Jensen, K.S., Enterkine, J., Boyd, C.S., et al., 2023, Estimates of fine fuel litter biomass in the northern Great Basin reveal increases during short fire-free intervals associated with invasive annual grasses: Science of the Total Environment, v. 860, article 160634, at https://doi.org/10.1016/j.scitotenv.2022.160634. |
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Climate change and vulnerability of bull trout (Salvelinus confluentus) in a fire-prone landscape | J. A. Falke, R. L. Flitcroft, J. B. Dunham, K. M. McNyset, P. F. Hessburg, G. H. Reeves, C. T. Marshall | 2015 | Falke, J.A., Flitcroft, R.L., Dunham, J.B., McNyset, K.M., Hessburg, P.F., Reeves, G.H., and Marshall, C.T., 2015, Climate change and vulnerability of bull trout (Salvelinus confluentus) in a fire-prone landscape: Canadian Journal of Fisheries & Aquatic Sciences, v. 72, no. 2, p. 304–318, at https://doi.org/10.1139/cjfas-2014-0098. |
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Thresholds and relations for soil-hydraulic and soil-physical properties as a function of burn severity 4 years after the 2011 Las Conchas Fire, New Mexico, USA | B. A. Ebel, O. C. Romero, D. A. Martin | 2018 | Ebel, B.A., Romero, O.C., and Martin, D.A., 2018, Thresholds and relations for soil-hydraulic and soil-physical properties as a function of burn severity 4 years after the 2011 Las Conchas Fire, New Mexico, USA: Hydrological Processes, v. 32, no. 14, p. 2263–2278, at https://doi.org/10.1002/hyp.13167. |
Post-fire temporal trends in soil-physical and -hydraulic properties and simulated runoff generation—Insights from different burn severities in the 2013 Black Forest Fire, CO, USA | B. A. Ebel, J. A. Moody, D. A. Martin | 2022 | Ebel, B.A., Moody, J.A., and Martin, D.A., 2022, Post-fire temporal trends in soil-physical and -hydraulic properties and simulated runoff generation—Insights from different burn severities in the 2013 Black Forest Fire, CO, USA: Science of the Total Environment, v. 802, article 149847, at https://doi.org/10.1016/j.scitotenv.2021.149847. |
Upper limits for post-wildfire floods and distinction from debris flows | B. A. Ebel | 2024 | Ebel, B.A., 2024, Upper limits for post-wildfire floods and distinction from debris flows: Science Advances, v. 10, article eadk5713, at https://doi.org/10.1126/sciadv.adk5713. |
Hotter drought escalates tree cover declines in blue oak woodlands of California | F. K. Dwomoh, J. F. Brown, H. J. Tollerud, R. F. Auch | 2021 | Dwomoh, F.K., Brown, J.F., Tollerud, H.J., and Auch, R.F., 2021, Hotter drought escalates tree cover declines in blue oak woodlands of California: Frontiers in Climate, v. 3, article 689945, at https://doi.org/10.3389/fclim.2021.689945. |
Trends in tree cover change over three decades related to interannual climate variability and wildfire in California | F. K. Dwomoh, R. F. Auch, J. Brown, H. J. Tollerud | 2023 | Dwomoh, F.K., Auch, R.F., Brown, J., and Tollerud, H.J., 2023, Trends in tree cover change over three decades related to interannual climate variability and wildfire in California: Environmental Research Letters, v. 18, no. 2, article 024007, at https://doi.org/10.1088/1748-9326/acad15. |
Ubiquitous fractal scaling and filtering behavior of hydrologic fluxes and storages from a mountain headwater catchment | R. Dwivedi, J. F. Knowles, C. Eastoe, R. Minor, N. Abramson, B. Mitra, W. E. Wright, J. McIntosh, T. Meixner, P. A. “Ty” Ferre, C. Castro, G.-Y. Niu, G. A. Barron-Gafford, M. Stanley, J. Chorover | 2020 | Dwivedi, R., Knowles, J.F., Eastoe, C., Minor, R., Abramson, N., Mitra, B., Wright, W.E., McIntosh, J., Meixner, T., et al., 2020, Ubiquitous fractal scaling and filtering behavior of hydrologic fluxes and storages from a mountain headwater catchment: Water, v. 12, no. 2, article 613, at https://doi.org/10.3390/w12020613. |
Long-term recovery of Mexican spotted owl nesting habitat after fire in the Lincoln National Forest, New Mexico | T. D. Durboraw, C. W. Boal, M. S. Fleck, N. S. Gill | 2022 | Durboraw, T.D., Boal, C.W., Fleck, M.S., and Gill, N.S., 2022, Long-term recovery of Mexican spotted owl nesting habitat after fire in the Lincoln National Forest, New Mexico: Fire Ecology, v. 18, no. 1, article 31, at https://doi.org/10.1186/s42408-022-00158-z. |
Tree mortality and structural change following mixed-severity fire in Pseudotsuga forests of Oregon’s western Cascades, USA | C. J. Dunn, J. D. Bailey | 2016 | Dunn, C.J., and Bailey, J.D., 2016, Tree mortality and structural change following mixed-severity fire in Pseudotsuga forests of Oregon’s western Cascades, USA: Forest Ecology and Management, v. 365, p. 107–118, at https://doi.org/10.1016/j.foreco.2016.01.031. |
Strengthened scientific support for the Endangerment Finding for atmospheric greenhouse gases | P. B. Duffy, C. B. Field, N. S. Diffenbaugh, S. C. Doney, Z. Dutton, S. Goodman, L. Heinzerling, S. Hsiang, D. B. Lobell, L. J. Mickley, S. Myers, S. M. Natali, C. Parmesan, S. Tierney, A. P. Williams | 2019 | Duffy, P.B., Field, C.B., Diffenbaugh, N.S., Doney, S.C., Dutton, Z., Goodman, S., Heinzerling, L., Hsiang, S., Lobell, D.B., et al., 2019, Strengthened scientific support for the Endangerment Finding for atmospheric greenhouse gases: Science, v. 363, no. 6427, article eaat5982, at https://doi.org/10.1126/science.aat5982. |
Large-scale wildfire reduces population growth in a peripheral population of sage-grouse | I. F. Dudley, P. S. Coates, B. G. Prochazka, S. T. O’Neil, S. Gardner, D. J. Delehanty | 2021 | Dudley, I.F., Coates, P.S., Prochazka, B.G., O’Neil, S.T., Gardner, S., and Delehanty, D.J., 2021, Large-scale wildfire reduces population growth in a peripheral population of sage-grouse: Fire Ecology, v. 17, no. 1, article 15, at https://doi.org/10.1186/s42408-021-00099-z. |
Maladaptive nest?site selection and reduced nest survival in female sage?grouse following wildfire | I. F. Dudley, P. S. Coates, B. G. Prochazka, D. M. Davis, S. C. Gardner, D. J. Delehanty | 2022 | Dudley, I.F., Coates, P.S., Prochazka, B.G., Davis, D.M., Gardner, S.C., and Delehanty, D.J., 2022, Maladaptive nest?site selection and reduced nest survival in female sage?grouse following wildfire: Ecosphere, v. 13, no. 12, article e4282, at https://doi.org/10.1002/ecs2.4282. |
Differential landscape use by forest owls two years after a mixed-severity wildfire | L. S. Duchac, D. B. Lesmeister, K. M. Dugger, R. J. Davis | 2021 | Duchac, L.S., Lesmeister, D.B., Dugger, K.M., and Davis, R.J., 2021, Differential landscape use by forest owls two years after a mixed-severity wildfire: Ecosphere, v. 12, no. 10, article e03770, at https://doi.org/10.1002/ecs2.3770. |
Monitoring annual land use/land cover change in the Tucson metropolitan area with Google Earth Engine (1986–2020) | F. Dubertret, F. M. L. Tourneau, M. L. Villarreal, L. M. Norman | 2022 | Dubertret, F., Tourneau, F.M.L., Villarreal, M.L., and Norman, L.M., 2022, Monitoring annual land use/land cover change in the Tucson metropolitan area with Google Earth Engine (1986–2020): Remote Sensing, v. 14, no. 9, article 2127, at https://doi.org/10.3390/rs14092127. |
Intercomparison of fire size, fuel loading, fuel consumption, and smoke emissions estimates on the 2006 tripod fire, Washington, USA | S. A. Drury, N. S. Larkin, T. T. Strand, S. Huang, S. J. Strenfel, E. M. Banwell, T. E. O'Brien, S. M. Raffuse | 2014 | Drury, S.A., Larkin, N.S., Strand, T.T., Huang, S., Strenfel, S.J., Banwell, E.M., O'Brien, T.E., and Raffuse, S.M., 2014, Intercomparison of fire size, fuel loading, fuel consumption, and smoke emissions estimates on the 2006 tripod fire, Washington, USA: Fire Ecology, v. 10, no. 1, p. 56–83, at https://doi.org/10.4996/fireecology.1001056. |
Assessing landscape change and processes of recurrence, replacement, and recovery in the southeastern coastal plains, USA | M. A. Drummond, M. P. Stier, R. F. Auch, J. L. Taylor, G. E. Griffith, J. L. Riegle, D. J. Hester, C. E. Soulard, J. L. McBeth | 2015 | Drummond, M.A., Stier, M.P., Auch, R.F., Taylor, J.L., Griffith, G.E., Riegle, J.L., Hester, D.J., Soulard, C.E., and McBeth, J.L., 2015, Assessing landscape change and processes of recurrence, replacement, and recovery in the southeastern coastal plains, USA: Environmental Management, v. 56, no. 5, p. 1252–71, at https://doi.org/10.1007/s00267-015-0574-1. |
Understanding recurrent land use processes and long-term transitions in the dynamic south-central United States, c. 1800 to 2006 | M. A. Drummond, G. E. Griffith, R. F. Auch, M. P. Stier, J. L. Taylor, D. J. Hester, J. L. Riegle, J. L. McBeth | 2017 | Drummond, M.A., Griffith, G.E., Auch, R.F., Stier, M.P., Taylor, J.L., Hester, D.J., Riegle, J.L., and McBeth, J.L., 2017, Understanding recurrent land use processes and long-term transitions in the dynamic south-central United States, c. 1800 to 2006: Land Use Policy, v. 68, p. 345–354, at https://doi.org/10.1016/j.landusepol.2017.07.061. |
Riparian ecosystems of the Manti-La Sal National Forest—An assessment of current conditions in relation to natural range of variability | Driscoll, K.P., Smith, D.M., Finch, D.M. | 2019 | Driscoll, K.P., Smith, D.M., and Finch, D.M., 2019, Riparian ecosystems of the Manti-La Sal National Forest—An assessment of current conditions in relation to natural range of variability: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-386, 160 p., at https://doi.org/10.2737/RMRS-GTR-386. |
Where and why do conifer forests persist in refugia through multiple fire events? | W. M. Downing, G. W. Meigs, M. J. Gregory, M. A. Krawchuk | 2021 | Downing, W.M., Meigs, G.W., Gregory, M.J., and Krawchuk, M.A., 2021, Where and why do conifer forests persist in refugia through multiple fire events?: Global Change Biology, v. 27, no. 15, p. 3642–3656, at https://doi.org/10.1111/gcb.15655. |
Influence of fire refugia spatial pattern on post-fire forest recovery in Oregon's Blue Mountains | W. M. Downing, M. A. Krawchuk, G. W. Meigs, S. L. Haire, J. D. Coop, R. B. Walker, E. Whitman, G. Chong, C. Miller | 2019 | Downing, W.M., Krawchuk, M.A., Meigs, G.W., Haire, S.L., Coop, J.D., Walker, R.B., Whitman, E., Chong, G., and Miller, C., 2019, Influence of fire refugia spatial pattern on post-fire forest recovery in Oregon's Blue Mountains: Landscape Ecology, v. 34, no. 4, p. 771–792, at https://doi.org/10.1007/s10980-019-00802-1. |
How do plant communities differ between fire refugia and fire?generated early?seral vegetation? | W. M. Downing, M. A. Krawchuk, J. D. Coop, G. W. Meigs, S. L. Haire, R. B. Walker, E. Whitman, G. Chong, C. Miller, C. Tortorelli, S. Roxburgh | 2019 | Downing, W.M., Krawchuk, M.A., Coop, J.D., Meigs, G.W., Haire, S.L., Walker, R.B., Whitman, E., Chong, G., Miller, C., et al., 2019, How do plant communities differ between fire refugia and fire?generated early?seral vegetation?: Journal of Vegetation Science, v. 31, no. 1, p. 26–39, at https://doi.org/10.1111/jvs.12814. |
Employing Copernicus Land Service and Sentinel-2 satellite mission data to assess the spatial dynamics and distribution of the extreme forest fires of 2023 in Greece | A. Dosiou, I. Athinelis, E. Katris, M. Vassalou, A. Kyrkos, P. Krassakis, I. Parcharidis | 2024 | Dosiou, A., Athinelis, I., Katris, E., Vassalou, M., Kyrkos, A., Krassakis, P., and Parcharidis, I., 2024, Employing Copernicus Land Service and Sentinel-2 satellite mission data to assess the spatial dynamics and distribution of the extreme forest fires of 2023 in Greece: Fire, v. 7, no. 1, article 20, at https://doi.org/10.3390/fire7010020. |
Land-use type as a driver of large wildfire occurrence in the U.S. Great Plains | V. M. Donovan, C. L. Wonkka, D. A. Wedin, D. Twidwell | 2020 | Donovan, V.M., Wonkka, C.L., Wedin, D.A., and Twidwell, D., 2020, Land-use type as a driver of large wildfire occurrence in the U.S. Great Plains: Remote Sensing, v. 12, no. 11, article 1869, at https://doi.org/10.3390/rs12111869. |
Surging wildfire activity in a grassland biome | V. M. Donovan, C. L. Wonkka, D. Twidwell | 2017 | Donovan, V.M., Wonkka, C.L., and Twidwell, D., 2017, Surging wildfire activity in a grassland biome: Geophysical Research Letters, v. 44, no. 12, p. 5986–5993, at https://doi.org/10.1002/2017gl072901. |
The influence of wildfire on invasive plant abundance and spatial structure in eastern ponderosa pine savanna | V. M. Donovan, C. L. Wonkka, C. P. Roberts, D. A. Wedin, D. A. McGranahan, D. Twidwell | 2023 | Donovan, V.M., Wonkka, C.L., Roberts, C.P., Wedin, D.A., McGranahan, D.A., and Twidwell, D., 2023, The influence of wildfire on invasive plant abundance and spatial structure in eastern ponderosa pine savanna: Plant Ecology, v. 224, p. 987–999, at https://doi.org/10.1007/s11258-023-01355-9. |
Resilience to large, “catastrophic” wildfires in North America's grassland biome | V. M. Donovan, D. Twidwell, D. R. Uden, T. Tadesse, B. D. Wardlow, C. H. Bielski, M. O. Jones, B. W. Allred, D. E. Naugle, C. R. Allen | 2020 | Donovan, V.M., Twidwell, D., Uden, D.R., Tadesse, T., Wardlow, B.D., Bielski, C.H., Jones, M.O., Allred, B.W., Naugle, D.E., and Allen, C.R., 2020, Resilience to large, “catastrophic” wildfires in North America's grassland biome: Earth's Future, v. 8, no. 7, article e2020EF001487, at https://doi.org/10.1029/2020EF001487. |
Ponderosa pine regeneration, wildland fuels management, and habitat conservation—Identifying trade-offs following wildfire | V. M. Donovan, C. P. Roberts, C. L. Wonkka, D. A. Wedin, D. Twidwell | 2019 | Donovan, V.M., Roberts, C.P., Wonkka, C.L., Wedin, D.A., and Twidwell, D., 2019, Ponderosa pine regeneration, wildland fuels management, and habitat conservation—Identifying trade-offs following wildfire: Forests, v. 10, no. 3, article 286, at https://doi.org/10.3390/f10030286. |
Collapse, reorganization, and regime identity—Breaking down past management paradigms in a forest-grassland ecotone | V. M. Donovan, C. P. Roberts, C. L. Wonkka, D. R. Uden, D. G. Angeler, C. R. Allen, D. A. Wedin, R. A. Drijber, D. Twidwell | 2021 | Donovan, V.M., Roberts, C.P., Wonkka, C.L., Uden, D.R., Angeler, D.G., Allen, C.R., Wedin, D.A., Drijber, R.A., and Twidwell, D., 2021, Collapse, reorganization, and regime identity—Breaking down past management paradigms in a forest-grassland ecotone: Ecology and Society, v. 26, no. 2, article 27, at https://doi.org/10.5751/es-12340-260227. |
Targeted grazing and mechanical thinning enhance forest stand resilience under a narrow range of wildfire scenarios | V. M. Donovan, C. P. Roberts, D. T. Fogarty, D. A. Wedin, D. Twidwell | 2022 | Donovan, V.M., Roberts, C.P., Fogarty, D.T., Wedin, D.A., and Twidwell, D., 2022, Targeted grazing and mechanical thinning enhance forest stand resilience under a narrow range of wildfire scenarios: Ecosphere, v. 13, no. 5, article e4061, at https://doi.org/10.1002/ecs2.4061. |
Relationships between wildfire burn severity, cavity-nesting bird assemblages, and habitat in an eastern ponderosa pine forest | V. M. Donovan, E. C. Keele, C. P. Roberts, S. M. Nodskov, C. L. Wonkka, C. R. Allen, L. A. Powell, D. A. Wedin, D. G. Angeler, D. Twidwell | 2019 | Donovan, V.M., Keele, E.C., Roberts, C.P., Nodskov, S.M., Wonkka, C.L., Allen, C.R., Powell, L.A., Wedin, D.A., Angeler, D.G., and Twidwell, D., 2019, Relationships between wildfire burn severity, cavity-nesting bird assemblages, and habitat in an eastern ponderosa pine forest: The American Midland Naturalist, v. 181, no. 1, p. 1–17, at https://doi.org/10.1674/0003-0031-181.1.1. |
Fire-driven landscape heterogeneity shapes habitat selection of bighorn sheep | V. M. Donovan, S. P. H. Dwinnell, J. L. Beck, C. P. Roberts, J. G. Clapp, G. S. Hiatt, K. L. Monteith, D. Twidwell | 2021 | Donovan, V.M., Dwinnell, S.P.H., Beck, J.L., Roberts, C.P., Clapp, J.G., Hiatt, G.S., Monteith, K.L., and Twidwell, D., 2021, Fire-driven landscape heterogeneity shapes habitat selection of bighorn sheep: Journal of Mammalogy, v. 102, no. 3, p. 757–771, at https://doi.org/10.1093/jmammal/gyab035. |
Increasing large wildfire in the eastern United States | V. M. Donovan, R. Crandall, J. Fill, C. L. Wonkka | 2023 | Donovan, V.M., Crandall, R., Fill, J., and Wonkka, C.L., 2023, Increasing large wildfire in the eastern United States: Geophysical Research Letters, v. 50, no. 24, article e2023GL107051, at https://doi.org/10.1029/2023GL107051. |
Declining pronghorn (Antilocapra americana) population productivity caused by woody encroachment and oil and gas development | V. M. Donovan, J. L. Beck, C. L. Wonkka, C. P. Roberts, C. R. Allen, D. Twidwell | 2024 | Donovan, V.M., Beck, J.L., Wonkka, C.L., Roberts, C.P., Allen, C.R., and Twidwell, D., 2024, Declining pronghorn (Antilocapra americana) population productivity caused by woody encroachment and oil and gas development: Global Ecology and Conservation, v. 50, article e02848, at https://doi.org/10.1016/j.gecco.2024.e02848. |
A probabilistic approach to post-wildfire debris-flow volume modeling | I. P. Donovan, P. M. Santi | 2017 | Donovan, I.P., and Santi, P.M., 2017, A probabilistic approach to post-wildfire debris-flow volume modeling: Landslides, v. 14, no. 4, p. 1345–1360, at https://doi.org/10.1007/s10346-016-0786-3. |
Meteorological environments associated with California wildfires and their potential roles in wildfire changes during 1984–2017 | L. Dong, L. R. Leung, Y. Qian, Y. F. Zou, F. F. Song, X. D. Chen | 2021 | Dong, L., Leung, L.R., Qian, Y., Zou, Y.F., Song, F.F., and Chen, X.D., 2021, Meteorological environments associated with California wildfires and their potential roles in wildfire changes during 1984–2017: Journal of Geophysical Research—Atmospheres, v. 126, no. 5, article e2020JD033180, at https://doi.org/10.1029/2020JD033180. |
Regeneration of montane forests 24 years after the 1988 Yellowstone fires—A fire-catalyzed shift in lower treelines? | D. C. Donato, B. J. Harvey, M. G. Turner | 2016 | Donato, D.C., Harvey, B.J., and Turner, M.G., 2016, Regeneration of montane forests 24 years after the 1988 Yellowstone fires—A fire-catalyzed shift in lower treelines?: Ecosphere, v. 7, no. 8, article e01410, at https://doi.org/10.1002/ecs2.1410. |
Does large area burned mean a bad fire year? Comparing contemporary wildfire years to historical fire regimes informs the restoration task in fire-dependent forests | D. C. Donato, J. S. Halofsky, D. J. Churchill, R. D. Haugo, C. Alina Cansler, A. Smith, B. J. Harvey | 2023 | Donato, D.C., Halofsky, J.S., Churchill, D.J., Haugo, R.D., Alina Cansler, C., Smith, A., and Harvey, B.J., 2023, Does large area burned mean a bad fire year? Comparing contemporary wildfire years to historical fire regimes informs the restoration task in fire-dependent forests: Forest Ecology and Management, v. 546, article 121372, at https://doi.org/10.1016/j.foreco.2023.121372. |
Southwestern ponderosa pine forest patterns following wildland fires managed for resource benefit differ from reference landscapes | J. J. Donager, A. J. Sánchez Meador, D. W. Huffman | 2022 | Donager, J.J., Sánchez Meador, A.J., and Huffman, D.W., 2022, Southwestern ponderosa pine forest patterns following wildland fires managed for resource benefit differ from reference landscapes: Landscape Ecology, v. 37, no. 1, p. 285–304, at https://doi.org/10.1007/s10980-021-01352-1. |
Short- and long-term effects of ponderosa pine fuel treatments intersected by the Egley Fire Complex, Oregon, USA | J. M. Dodge, E. K. Strand, A. T. Hudak, B. C. Bright, D. H. Hammond, B. A. Newingham | 2019 | Dodge, J.M., Strand, E.K., Hudak, A.T., Bright, B.C., Hammond, D.H., and Newingham, B.A., 2019, Short- and long-term effects of ponderosa pine fuel treatments intersected by the Egley Fire Complex, Oregon, USA: Fire Ecology, v. 15, no. 1, article 40, at https://doi.org/10.1186/s42408-019-0055-7. |
Aridity drives phylogenetic diversity and species richness patterns of nitrogen?fixing plants in North America | J. R. Doby, D. Li, R. A. Folk, C. M. Siniscalchi, R. P. Guralnick | 2022 | Doby, J.R., Li, D., Folk, R.A., Siniscalchi, C.M., and Guralnick, R.P., 2022, Aridity drives phylogenetic diversity and species richness patterns of nitrogen?fixing plants in North America: Global Ecology and Biogeography, v. 31, no. 8, p. 1630–1642, at https://doi.org/10.1111/geb.13535. |
Water quality and forest restoration in the Lake Tahoe Basin—Impacts of future management options | M. Dobre, J. W. Long, C. Maxwell, W. J. Elliot, R. Lew, E. S. Brooks, R. M. Scheller | 2022 | Dobre, M., Long, J.W., Maxwell, C., Elliot, W.J., Lew, R., Brooks, E.S., and Scheller, R.M., 2022, Water quality and forest restoration in the Lake Tahoe Basin—Impacts of future management options: Ecology and Society, v. 27, no. 2, article 6, at https://doi.org/10.5751/es-13133-270206. |
Satellite detection of canopy-scale tree mortality and survival from California wildfires with spatio-temporal deep learning | D. J. Dixon, Y. Zhu, C. F. Brown, Y. Jin | 2023 | Dixon, D.J., Zhu, Y., Brown, C.F., and Jin, Y., 2023, Satellite detection of canopy-scale tree mortality and survival from California wildfires with spatio-temporal deep learning: Remote Sensing of Environment, v. 298, article 113842, at https://doi.org/10.1016/j.rse.2023.113842. |
Influence of environmental change, harvest exposure, and human disturbance on population trends of greater sage-grouse | J. B. Dinkins, K. J. Lawson, J. L. Beck | 2021 | Dinkins, J.B., Lawson, K.J., and Beck, J.L., 2021, Influence of environmental change, harvest exposure, and human disturbance on population trends of greater sage-grouse: PLoS ONE, v. 16, no. 9, article e0257198, at https://doi.org/10.1371/journal.pone.0257198. |
Long-term persistence of desert rodent species in a Great Basin sagebrush community—Potential effects of fire, invasive annuals, and warming temperatures | L. A. Dimitri, W. S. Longland | 2022 | Dimitri, L.A., and Longland, W.S., 2022, Long-term persistence of desert rodent species in a Great Basin sagebrush community—Potential effects of fire, invasive annuals, and warming temperatures: Western North American Naturalist, v. 82, no. 3, p. 603–610, at https://doi.org/10.3398/064.082.0316. |
Pygmy rabbit habitat network reveals threats and opportunities for management and conservation | T. E. Dilts, K. A. Zeller, S. A. Cushman, E. S. Larrucea, M. M. Crowell, N. W. Byer, K. T. Shoemaker, M. D. Matocq | 2023 | Dilts, T.E., Zeller, K.A., Cushman, S.A., Larrucea, E.S., Crowell, M.M., Byer, N.W., Shoemaker, K.T., and Matocq, M.D., 2023, Pygmy rabbit habitat network reveals threats and opportunities for management and conservation: Landscape Ecology, v. 38, p. 1971–1989, at https://doi.org/10.1007/s10980-023-01672-4. |
Functionally relevant climate variables for arid lands—A climatic water deficit approach for modelling desert shrub distributions | T. E. Dilts, P. J. Weisberg, C. M. Dencker, J. C. Chambers | 2015 | Dilts, T.E., Weisberg, P.J., Dencker, C.M., and Chambers, J.C., 2015, Functionally relevant climate variables for arid lands—A climatic water deficit approach for modelling desert shrub distributions: Journal of Biogeography, v. 42, no. 10, p. 1986–1997, at https://doi.org/10.1111/jbi.12561. |
Development of a severe fire potential map for the contiguous United States | Dillon, G. K., Panunto, M. H., Davis, B., Morgan, P., Birch, D. S., Jolly, W. M. | 2020 | Dillon, G.K., Panunto, M.H., Davis, B., Morgan, P., Birch, D.S., and Jolly, W.M., 2020, Development of a severe fire potential map for the contiguous United States: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRSGTR-415, 107 p., at https://www.fs.usda.gov/treesearch/pubs/60733. |
Wildland fire potential—A tool for assessing wildfire risk and fuels management needs | Dillon, G.K., Menakis, J. P., Fay, F. | 2015 | Dillon, G.K., Menakis, J.P., and Fay, F., 2015, Wildland fire potential—A tool for assessing wildfire risk and fuels management needs, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 60–76, at https://www.fs.usda.gov/treesearch/pubs/49429. |
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The relative importance of biotic and abiotic factors influencing aspen recruitment in Arizona | M. J. Clement, L. E. Harding, R. W. Lucas, E. S. Rubin | 2019 | Clement, M.J., Harding, L.E., Lucas, R.W., and Rubin, E.S., 2019, The relative importance of biotic and abiotic factors influencing aspen recruitment in Arizona: Forest Ecology and Management, v. 441, p. 32–41, at https://doi.org/10.1016/j.foreco.2019.03.026. |
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Watershed-scale vegetation, water quantity, and water quality responses to wildfire in the southern Appalachian Mountain region, United States | P. V. Caldwell, K. J. Elliott, N. Liu, J. M. Vose, D. R. Zietlow, J. D. Knoepp | 2020 | Caldwell, P.V., Elliott, K.J., Liu, N., Vose, J.M., Zietlow, D.R., and Knoepp, J.D., 2020, Watershed-scale vegetation, water quantity, and water quality responses to wildfire in the southern Appalachian Mountain region, United States: Hydrological Processes, v. 34, no. 26, p. 5188–5209, at https://doi.org/10.1002/hyp.13922. |
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High-severity and short-interval wildfires limit forest recovery in the Central Cascade Range | S. U. Busby, K. B. Moffett, A. Holz | 2020 | Busby, S.U., Moffett, K.B., and Holz, A., 2020, High-severity and short-interval wildfires limit forest recovery in the Central Cascade Range: Ecosphere, v. 11, no. 9, article e03247, at https://doi.org/10.1002/ecs2.3247. |
Inventory analysis of fire effects wrought by wind-driven megafires in relation to weather and pre-fire forest structure in the western Cascades | S. U. Busby, A. M. Klock, J. S. Fried | 2023 | Busby, S.U., Klock, A.M., and Fried, J.S., 2023, Inventory analysis of fire effects wrought by wind-driven megafires in relation to weather and pre-fire forest structure in the western Cascades: Fire Ecology, v. 19, no. 1, article 58, at https://doi.org/10.1186/s42408-023-00219-x. |
Interactions between fire refugia and climate-environment conditions determine mesic subalpine forest recovery after large and severe wildfires | S. U. Busby, A. Holz | 2022 | Busby, S.U., and Holz, A., 2022, Interactions between fire refugia and climate-environment conditions determine mesic subalpine forest recovery after large and severe wildfires: Frontiers in Forests and Global Change, v. 5, article 890893, at https://doi.org/10.3389/ffgc.2022.890893. |
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Factors influencing flood risk mitigation after wildfire—Insights for individual and collective action after the 2010 Schultz Fire | J. T. Burnett, C. M. Edgeley | 2023 | Burnett, J.T., and Edgeley, C.M., 2023, Factors influencing flood risk mitigation after wildfire—Insights for individual and collective action after the 2010 Schultz Fire: International Journal of Disaster Risk Reduction, v. 94, article 103791, at https://doi.org/10.1016/j.ijdrr.2023.103791. |
Wildfires influence abundance, diversity, and intraspecific and interspecific trait variation of native bees and flowering plants across burned and unburned landscapes | L. A. Burkle, M. P. Simanonok, J. S. Durney, J. A. Myers, R. T. Belote | 2019 | Burkle, L.A., Simanonok, M.P., Durney, J.S., Myers, J.A., and Belote, R.T., 2019, Wildfires influence abundance, diversity, and intraspecific and interspecific trait variation of native bees and flowering plants across burned and unburned landscapes: Frontiers in Ecology and Evolution, v. 7, article 252, at https://doi.org/10.3389/fevo.2019.00252. |
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Does high-severity patch structure scale consistently with fire size across the northwest US? Final Report | Buonanduci, M.S., Harvey, B.J. | 2023 | Buonanduci, M.S., and Harvey, B.J., 2023, Does high-severity patch structure scale consistently with fire size across the northwest US? Final Report: Joint Fire Science Program JFSP PROJECT ID—21-1-01-26, 32 p., at https://www.firescience.gov/projects/21-1-01-26/project/21-1-01-26_final_report.pdf. |
Consistent spatial scaling of high-severity wildfire can inform expected future patterns of burn severity | M. S. Buonanduci, D. C. Donato, J. S. Halofsky, M. C. Kennedy, B. J. Harvey | 2023 | Buonanduci, M.S., Donato, D.C., Halofsky, J.S., Kennedy, M.C., and Harvey, B.J., 2023, Consistent spatial scaling of high-severity wildfire can inform expected future patterns of burn severity: Ecology Letters, v. 26, no. 10, p. 1687–1699, at https://doi.org/10.1111/ele.14282. |
Climate legacy and lag effects on dryland plant communities in the southwestern U.S | E. L. Bunting, S. M. Munson, M. L. Villarreal | 2017 | Bunting, E.L., Munson, S.M., and Villarreal, M.L., 2017, Climate legacy and lag effects on dryland plant communities in the southwestern U.S: Ecological Indicators, v. 74, p. 216–229, at https://doi.org/10.1016/j.ecolind.2016.10.024. |
Assessing plant production responses to climate across water-limited regions using Google Earth Engine | E. L. Bunting, S. M. Munson, J. B. Bradford | 2019 | Bunting, E.L., Munson, S.M., and Bradford, J.B., 2019, Assessing plant production responses to climate across water-limited regions using Google Earth Engine: Remote Sensing of Environment, v. 233, article 111379, at https://doi.org/10.1016/j.rse.2019.111379. |
Wildland fire reburning trends across the US West suggest only short-term negative feedback and differing climatic effects | B. Buma, S. Weiss, K. Hayes, M. Lucash | 2020 | Buma, B., Weiss, S., Hayes, K., and Lucash, M., 2020, Wildland fire reburning trends across the US West suggest only short-term negative feedback and differing climatic effects: Environmental Research Letters, v. 15, no. 3, article 034026, at https://doi.org/10.1088/1748-9326/ab6c70. |
Short?interval fires increasing in the Alaskan boreal forest as fire self?regulation decays across forest types | B. Buma, K. Hayes, S. Weiss, M. Lucash | 2022 | Buma, B., Hayes, K., Weiss, S., and Lucash, M., 2022, Short?interval fires increasing in the Alaskan boreal forest as fire self?regulation decays across forest types: Scientific Reports, v. 12, no. 1, article 4901, at https://doi.org/10.1038/s41598-022-08912-8. |
SMLFire1.0—A stochastic machine learning (SML) model for wildfire activity in the western United States | J. Buch, A. P. Williams, C. S. Juang, W. D. Hansen, P. Gentine | 2023 | Buch, J., Williams, A.P., Juang, C.S., Hansen, W.D., and Gentine, P., 2023, SMLFire1.0—A stochastic machine learning (SML) model for wildfire activity in the western United States: Geoscientific Model Development, v. 16, no. 12, p. 3407–3433, at https://doi.org/10.5194/gmd-16-3407-2023. |
Invasion of annual grasses following wildfire corresponds to maladaptive habitat selection by a sagebrush ecosystem indicator species | B. E. Brussee, P. S. Coates, S. T. O’Neil, M. L. Casazza, S. P. Espinosa, J. D. Boone, E. M. Ammon, S. C. Gardner, D. J. Delehanty | 2022 | Brussee, B.E., Coates, P.S., O’Neil, S.T., Casazza, M.L., Espinosa, S.P., Boone, J.D., Ammon, E.M., Gardner, S.C., and Delehanty, D.J., 2022, Invasion of annual grasses following wildfire corresponds to maladaptive habitat selection by a sagebrush ecosystem indicator species: Global Ecology and Conservation, v. 37, article e02147, at https://doi.org/10.1016/j.gecco.2022.e02147. |
Exploring relationships of spring green-up to moisture and temperature across Wyoming, U.S.A. | J. F. Brown, L. Ji, A. Gallant, M. Kauffman | 2018 | Brown, J.F., Ji, L., Gallant, A., and Kauffman, M., 2018, Exploring relationships of spring green-up to moisture and temperature across Wyoming, U.S.A.: International Journal of Remote Sensing, v. 40, no. 3, p. 956–984, at https://doi.org/10.1080/01431161.2018.1519642. |
US wildfire potential—A historical view and future projection using high-resolution climate data | E. K. Brown, J. Wang, Y. Feng | 2021 | Brown, E.K., Wang, J., and Feng, Y., 2021, US wildfire potential—A historical view and future projection using high-resolution climate data: Environmental Research Letters, v. 16, no. 3, article 034060, at https://doi.org/10.1088/1748-9326/aba868. |
Landscape effects of wildfire on permafrost distribution in interior Alaska derived from remote sensing | D. Brown, M. Jorgenson, K. Kielland, D. Verbyla, A. Prakash, J. Koch | 2016 | Brown, D., Jorgenson, M., Kielland, K., Verbyla, D., Prakash, A., and Koch, J., 2016, Landscape effects of wildfire on permafrost distribution in interior Alaska derived from remote sensing: Remote Sensing, v. 8, no. 8, article 654, at https://doi.org/10.3390/rs8080654. |
Remote sensing techniques to assess post-fire effects at the hillslope and sub-basin scales via multi-scale model | Brook, A., Polinova, M., Kopel, D., Malkinson, D., Wittenberg, L., Roberts, D., Shtober-Zisu, N. | 2017 | Brook, A., Polinova, M., Kopel, D., Malkinson, D., Wittenberg, L., Roberts, D., and Shtober-Zisu, N., 2017, Remote sensing techniques to assess post-fire effects at the hillslope and sub-basin scales via multi-scale model, in ISPRS Hannover Workshop—HRIGI 17 - CMRT 17 - ISA 17 - EuroCOW 17, Hannover, Germany, 6–9 June 2017, ISPRS Archives XLII-1/W1, 2: International Society for Photogrammetry and Remote Sensing, p. 135–141, at https://doi.org/10.5194/isprs-archives-XLII-1-W1-135-2017. |
Mapping multiple insect outbreaks across large regions annually using Landsat time series data | B. C. Bright, A. T. Hudak, A. J. H. Meddens, J. M. Egan, C. L. Jorgensen | 2020 | Bright, B.C., Hudak, A.T., Meddens, A.J.H., Egan, J.M., and Jorgensen, C.L., 2020, Mapping multiple insect outbreaks across large regions annually using Landsat time series data: Remote Sensing, v. 12, no. 10, article 1655, at https://doi.org/10.3390/rs12101655. |
Multitemporal lidar captures heterogeneity in fuel loads and consumption on the Kaibab Plateau | B. C. Bright, A. T. Hudak, T. R. McCarley, A. Spannuth, N. Sánchez-López, R. D. Ottmar, A. J. Soja | 2022 | Bright, B.C., Hudak, A.T., McCarley, T.R., Spannuth, A., Sánchez-López, N., Ottmar, R.D., and Soja, A.J., 2022, Multitemporal lidar captures heterogeneity in fuel loads and consumption on the Kaibab Plateau: Fire Ecology, v. 18, no. 1, article 18, at https://doi.org/10.1186/s42408-022-00142-7. |
Landsat time series and lidar as predictors of live and dead basal area across five bark beetle-affected forests | B. C. Bright, A. T. Hudak, R. E. Kennedy, A. J. H. Meddens | 2014 | Bright, B.C., Hudak, A.T., Kennedy, R.E., and Meddens, A.J.H., 2014, Landsat time series and lidar as predictors of live and dead basal area across five bark beetle-affected forests: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, v. 7, no. 8, p. 3440–3452, at https://doi.org/10.1109/JSTARS.2014.2346955. |
Examining post-fire vegetation recovery with Landsat time series analysis in three western North American forest types | B. C. Bright, A. T. Hudak, R. E. Kennedy, J. D. Braaten, A. H. Khalyani | 2019 | Bright, B.C., Hudak, A.T., Kennedy, R.E., Braaten, J.D., and Khalyani, A.H., 2019, Examining post-fire vegetation recovery with Landsat time series analysis in three western North American forest types: Fire Ecology, v. 15, article 8, at https://doi.org/10.1186/s42408-018-0021-9. |
Past variance and future projections of the environmental conditions driving western U.S. summertime wildfire burn area | S. J. Brey, E. A. Barnes, J. R. Pierce, A. L. S. Swann, E. V. Fischer | 2020 | Brey, S.J., Barnes, E.A., Pierce, J.R., Swann, A.L.S., and Fischer, E.V., 2020, Past variance and future projections of the environmental conditions driving western U.S. summertime wildfire burn area: Earth's Future, v. 9, no. 2, article e2020EF001645, at https://doi.org/10.1029/2020EF001645. |
Less fuel for the next fire? Short-interval fire delays forest recovery and interacting drivers amplify effects | K. H. Braziunas, N. G. Kiel, M. G. Turner | 2023 | Braziunas, K.H., Kiel, N.G., and Turner, M.G., 2023, Less fuel for the next fire? Short-interval fire delays forest recovery and interacting drivers amplify effects: Ecology, v. 104, no. 6, article e4042, at https://doi.org/10.1002/ecy.4042. |
Looking beyond the mean—Drivers of variability in postfire stand development of conifers in Greater Yellowstone | K. H. Braziunas, W. D. Hansen, R. Seidl, W. Rammer, M. G. Turner | 2018 | Braziunas, K.H., Hansen, W.D., Seidl, R., Rammer, W., and Turner, M.G., 2018, Looking beyond the mean—Drivers of variability in postfire stand development of conifers in Greater Yellowstone: Forest Ecology and Management, v. 430, p. 460–471, at https://doi.org/10.1016/j.foreco.2018.08.034. |
Young forests and fire—Using lidar-imagery fusion to explore fuels and burn severity in a subalpine forest reburn | K. H. Braziunas, D. C. Abendroth, M. G. Turner | 2022 | Braziunas, K.H., Abendroth, D.C., and Turner, M.G., 2022, Young forests and fire—Using lidar-imagery fusion to explore fuels and burn severity in a subalpine forest reburn: Ecosphere, v. 13, no. 5, article e4096, at https://doi.org/10.1002/ecs2.4096. |
Does increased forest protection correspond to higher fire severity in frequent-fire forests of the western United States? | C. M. Bradley, C. T. Hanson, D. A. DellaSala | 2016 | Bradley, C.M., Hanson, C.T., and DellaSala, D.A., 2016, Does increased forest protection correspond to higher fire severity in frequent-fire forests of the western United States?: Ecosphere, v. 7, no. 10, article e01492, at https://doi.org/10.1002/ecs2.1492. |
Fusing MODIS with Landsat 8 data to downscale weekly normalized difference vegetation index estimates for central Great Basin rangelands, USA | S. P. Boyte, B. K. Wylie, M. B. Rigge, D. Dahal | 2017 | Boyte, S.P., Wylie, B.K., Rigge, M.B., and Dahal, D., 2017, Fusing MODIS with Landsat 8 data to downscale weekly normalized difference vegetation index estimates for central Great Basin rangelands, USA: GIScience & Remote Sensing, v. 55, no. 3, p. 376–399, at https://doi.org/10.1080/15481603.2017.1382065. |
Validating a time series of annual grass percent cover in the sagebrush ecosystem | S. P. Boyte, B. K. Wylie, D. J. Major | 2019 | Boyte, S.P., Wylie, B.K., and Major, D.J., 2019, Validating a time series of annual grass percent cover in the sagebrush ecosystem: Rangeland Ecology & Management, v. 72, no. 2, p. 347–359, at https://doi.org/10.1016/j.rama.2018.09.004. |
Mapping and monitoring cheatgrass dieoff in rangelands of the northern Great Basin, USA | S. P. Boyte, B. K. Wylie, D. J. Major | 2015 | Boyte, S.P., Wylie, B.K., and Major, D.J., 2015, Mapping and monitoring cheatgrass dieoff in rangelands of the northern Great Basin, USA: Rangeland Ecology & Management, v. 68, no. 1, p. 18–28, at https://doi.org/10.1016/j.rama.2014.12.005. |
Estimating abiotic thresholds for sagebrush condition class in the western United States | S. P. Boyte, B. K. Wylie, Y. Gu, D. J. Major | 2020 | Boyte, S.P., Wylie, B.K., Gu, Y., and Major, D.J., 2020, Estimating abiotic thresholds for sagebrush condition class in the western United States: Rangeland Ecology & Management, v. 73, no. 2, p. 297–308, at https://doi.org/10.1016/j.rama.2019.10.010. |
Near-real-time cheatgrass percent cover in the northern Great Basin, USA, 2015 | S. P. Boyte, B. K. Wylie | 2016 | Boyte, S.P., and Wylie, B.K., 2016, Near-real-time cheatgrass percent cover in the northern Great Basin, USA, 2015: Rangelands, v. 38, no. 5, p. 278–284, at https://doi.org/10.1016/j.rala.2016.08.002. |
Fire and local factors shape ectomycorrhizal fungal communities associated with Pinus ponderosa in mountains of the Madrean Sky Island Archipelago | E. A. Bowman, D. R. Hayden, A. E. Arnold | 2021 | Bowman, E.A., Hayden, D.R., and Arnold, A.E., 2021, Fire and local factors shape ectomycorrhizal fungal communities associated with Pinus ponderosa in mountains of the Madrean Sky Island Archipelago: Fungal Ecology, v. 49, article 101013, at https://doi.org/10.1016/j.funeco.2020.101013. |
Human exposure and sensitivity to globally extreme wildfire events | D. M. J. S. Bowman, G. J. Williamson, J. T. Abatzoglou, C. A. Kolden, M. A. Cochrane, A. M. S. Smith | 2017 | Bowman, D.M.J.S., Williamson, G.J., Abatzoglou, J.T., Kolden, C.A., Cochrane, M.A., and Smith, A.M.S., 2017, Human exposure and sensitivity to globally extreme wildfire events: Nature Ecology & Evolution, v. 1, article 0058, at https://doi.org/10.1038/s41559-016-0058. |
Vegetation fires in the Anthropocene | D. Bowman, C. A. Kolden, J. T. Abatzoglou, F. H. Johnston, G. R. van der Werf, M. Flannigan | 2020 | Bowman, D., Kolden, C.A., Abatzoglou, J.T., Johnston, F.H., van der Werf, G.R., and Flannigan, M., 2020, Vegetation fires in the Anthropocene: Nature Reviews Earth & Environment, v. 1, no. 10, p. 500–515, at https://doi.org/10.1038/s43017-020-0085-3. |
MODIS–Landsat fusion for large area 30 m burned area mapping | L. Boschetti, D. P. Roy, C. O. Justice, M. L. Humber | 2015 | Boschetti, L., Roy, D.P., Justice, C.O., and Humber, M.L., 2015, MODIS–Landsat fusion for large area 30 m burned area mapping: Remote Sensing of Environment, v. 161, p. 27–42, at https://doi.org/10.1016/j.rse.2015.01.022. |
Long-term vegetation response following post-fire straw mulching | J. D. Bontrager, P. Morgan, A. T. Hudak, P. R. Robichaud | 2019 | Bontrager, J.D., Morgan, P., Hudak, A.T., and Robichaud, P.R., 2019, Long-term vegetation response following post-fire straw mulching: Fire Ecology, v. 15, no. 1, article 22, at https://doi.org/10.1186/s42408-019-0037-9. |
Forest management, barred owls, and wildfire in northern spotted owl territories | M. L. Bond, T. Y. Chi, C. M. Bradley, D. A. DellaSala | 2022 | Bond, M.L., Chi, T.Y., Bradley, C.M., and DellaSala, D.A., 2022, Forest management, barred owls, and wildfire in northern spotted owl territories: Forests, v. 13, no. 10, article 1730, at https://doi.org/10.3390/f13101730. |
Foraging habitat selection by California spotted owls after fire | M. L. Bond, C. Bradley, D. E. Lee | 2016 | Bond, M.L., Bradley, C., and Lee, D.E., 2016, Foraging habitat selection by California spotted owls after fire: The Journal of Wildlife Management, v. 80, no. 7, p. 1290–1300, at https://doi.org/10.1002/jwmg.21112. |
Multi-scale analysis of jack pine saplings after fire across burn severities | Bomber, M., Portelli, R. | 2020 | Bomber, M., and Portelli, R., 2020, Multi-scale analysis of jack pine saplings after fire across burn severities, in XXIV ISPRS Congress, online, 2020 edition, ISPRS Archives XLIII-B3: International Society for Photogrammetry and Remote Sensing, p. 671–675, at https://doi.org/10.5194/isprs-archives-XLIII-B3-2020-671-2020. |
Effects of wildfire on riparian trees in southeastern Arizona | C. E. Bock, J. H. Bock | 2014 | Bock, C.E., and Bock, J.H., 2014, Effects of wildfire on riparian trees in southeastern Arizona: The Southwestern Naturalist, v. 59, no. 4, p. 570–576, at https://doi.org/10.1894/JEM-08.1. |
Fire patterns in piñon and juniper land cover types in the semiarid western United States from 1984 through 2013 | Board, D.I., Chambers, J.C., Miller, R.F., Weisberg, P.J. | 2018 | Board, D.I., Chambers, J.C., Miller, R.F., and Weisberg, P.J., 2018, Fire patterns in piñon and juniper land cover types in the semiarid western United States from 1984 through 2013: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-372, 57 p., at https://doi.org/10.2737/RMRS-GTR-372. |
Topography and fire legacies drive variable post-fire juvenile conifer regeneration in eastern Oregon, USA | A. E. Boag, M. J. Ducey, M. W. Palace, J. Hartter | 2020 | Boag, A.E., Ducey, M.J., Palace, M.W., and Hartter, J., 2020, Topography and fire legacies drive variable post-fire juvenile conifer regeneration in eastern Oregon, USA: Forest Ecology and Management, v. 474, article 118312, at https://doi.org/10.1016/j.foreco.2020.118312. |
Increased water yield and altered water partitioning follow wildfire in a forested catchment in the western United States | K. Blount, C. J. Ruybal, K. J. Franz, T. S. Hogue | 2020 | Blount, K., Ruybal, C.J., Franz, K.J., and Hogue, T.S., 2020, Increased water yield and altered water partitioning follow wildfire in a forested catchment in the western United States: Ecohydrology, v. 13, no. 1, article e2170, at https://doi.org/10.1002/eco.2170. |
The compounding consequences of wildfire and climate change for a high-elevation wildflower (Saxifraga austromontana) | T. D. S. Bloom, A. Flower, M. Medler, E. G. DeChaine | 2018 | Bloom, T.D.S., Flower, A., Medler, M., and DeChaine, E.G., 2018, The compounding consequences of wildfire and climate change for a high-elevation wildflower (Saxifraga austromontana): Journal of Biogeography, v. 45, no. 12, p. 2755–2765, at https://doi.org/10.1111/jbi.13441. |
Wildfire risk, salience, and housing development in the wildland–urban interface | K. J. Black, N. B. Irwin, S. J. McCoy | 2023 | Black, K.J., Irwin, N.B., and McCoy, S.J., 2023, Wildfire risk, salience, and housing development in the wildland–urban interface: Journal of Regional Science, v. 63, no. 4, p. 922–946, at https://doi.org/10.1111/jors.12644. |
Assessing beaver habitat on federal lands in New Mexico, Final Report | Bird, Bryan, Menke, K., Budrow, D., Hebert, D., Nguyen, A., Roybal, J. | 2013 | Bird, B., Menke, K., Budrow, D., Hebert, D., Nguyen, A., and Roybal, J., 2013, Assessing beaver habitat on federal lands in New Mexico, Final Report: WildEarth Guardians, 23 p., at https://wildearthguardians.org/about-us/research-reports/. |
Fire regimes of Utah—The past as prologue | J. D. Birch, J. A. Lutz | 2023 | Birch, J.D., and Lutz, J.A., 2023, Fire regimes of Utah—The past as prologue: Fire, v. 6, no. 11, article 423, at https://doi.org/10.3390/fire6110423. |
Heading and backing fire behaviours mediate the influence of fuels on wildfire energy | J. D. Birch, M. B. Dickinson, A. Reiner, E. E. Knapp, S. N. Dailey, C. Ewell, J. A. Lutz, J. R. Miesel | 2023 | Birch, J.D., Dickinson, M.B., Reiner, A., Knapp, E.E., Dailey, S.N., Ewell, C., Lutz, J.A., and Miesel, J.R., 2023, Heading and backing fire behaviours mediate the influence of fuels on wildfire energy: International Journal of Wildland Fire, v. 32, no. 8, p. 1244–1261, at https://doi.org/10.1071/WF22010. |
Is proportion burned severely related to daily area burned? | D. S. Birch, P. Morgan, C. A. Kolden, A. T. Hudak, A. M. S. Smith | 2014 | Birch, D.S., Morgan, P., Kolden, C.A., Hudak, A.T., and Smith, A.M.S., 2014, Is proportion burned severely related to daily area burned?: Environmental Research Letters, v. 9, no. 6, article 064011, at https://doi.org/10.1088/1748-9326/9/6/064011. |
Vegetation, topography and daily weather influenced burn severity in central Idaho and western Montana forests | D. S. Birch, P. Morgan, C. A. Kolden, J. T. Abatzoglou, G. K. Dillon, A. T. Hudak, A. M. S. Smith | 2015 | Birch, D.S., Morgan, P., Kolden, C.A., Abatzoglou, J.T., Dillon, G.K., Hudak, A.T., and Smith, A.M.S., 2015, Vegetation, topography and daily weather influenced burn severity in central Idaho and western Montana forests: Ecosphere, v. 6, no. 1, article 17, at https://doi.org/10.1890/ES14-00213.1. |
Santa Ana winds and predictors of wildfire progression in southern California | M. Billmire, N. H. F. French, T. Loboda, R. C. Owen, M. Tyner | 2014 | Billmire, M., French, N.H.F., Loboda, T., Owen, R.C., and Tyner, M., 2014, Santa Ana winds and predictors of wildfire progression in southern California: International Journal of Wildland Fire, v. 23, no. 8, p. 1119–1129, at https://doi.org/10.1071/WF13046. |
Late Holocene fire-climate relationships of the western San Juan Mountains, Colorado | E. R. Bigio, T. W. Swetnam, P. A. Pearthree | 2017 | Bigio, E.R., Swetnam, T.W., and Pearthree, P.A., 2017, Late Holocene fire-climate relationships of the western San Juan Mountains, Colorado: International Journal of Wildland Fire, v. 26, no. 11, p. 944–962, at https://doi.org/10.1071/WF16204. |
Variable wildfire impacts on the seasonal water temperatures of western US streams—A retrospective study | M. T. Beyene, S. G. Leibowitz, M. Snyder, J. L. Ebersole, V. W. Almquist | 2022 | Beyene, M.T., Leibowitz, S.G., Snyder, M., Ebersole, J.L., and Almquist, V.W., 2022, Variable wildfire impacts on the seasonal water temperatures of western US streams—A retrospective study: PLoS ONE, v. 17, no. 7, article e0268452, at https://doi.org/10.1371/journal.pone.0268452. |
Parsing weather variability and wildfire effects on the post?fire changes in extreme daily stream flows—A quantile?based statistical approach and its application | M. T. Beyene, S. G. Leibowitz, M. J. Pennino | 2021 | Beyene, M.T., Leibowitz, S.G., and Pennino, M.J., 2021, Parsing weather variability and wildfire effects on the post?fire changes in extreme daily stream flows—A quantile?based statistical approach and its application: Water Resources Research, v. 57, no. 10, article e2020WR028029, at https://doi.org/10.1029/2020wr028029. |
To burn or not to burn—An empirical assessment of the impacts of wildfires and prescribed fires on trace element concentrations in western US streams | M. T. Beyene, S. G. Leibowitz, C. J. Dunn, K. D. Bladon | 2022 | Beyene, M.T., Leibowitz, S.G., Dunn, C.J., and Bladon, K.D., 2022, To burn or not to burn—An empirical assessment of the impacts of wildfires and prescribed fires on trace element concentrations in western US streams: Science of the Total Environment, v. 863, article 160731, at https://doi.org/10.1016/j.scitotenv.2022.160731. |
Heterogeneity in post-fire thermal responses across Pacific Northwest streams—A multi-site study | M. T. Beyene, S. G. Leibowitz | 2024 | Beyene, M.T., and Leibowitz, S.G., 2024, Heterogeneity in post-fire thermal responses across Pacific Northwest streams—A multi-site study: Journal of Hydrology X, v. 23, article 100173, at https://doi.org/10.1016/j.hydroa.2024.100173. |
Structural diversity and development in active fire regime mixed-conifer forests | J. K. Berkey, R. T. Belote, C. T. Maher, A. J. Larson | 2021 | Berkey, J.K., Belote, R.T., Maher, C.T., and Larson, A.J., 2021, Structural diversity and development in active fire regime mixed-conifer forests: Forest Ecology and Management, v. 479, article 118548, at https://doi.org/10.1016/j.foreco.2020.118548. |
Wildfire across agricultural landscapes—Farmer and rancher experiences and perceptions in the southern Great Plains | J. S. Bergtold, M. M. Caldas, A. Joslin, M. Gharib | in press | Bergtold, J.S., Caldas, M.M., Joslin, A., and Gharib, M., in press, Wildfire across agricultural landscapes—Farmer and rancher experiences and perceptions in the southern Great Plains: Environmental Hazards, at https://doi.org/10.1080/17477891.2024.2304201. |
Distribution and frequency of wildfire in California riparian ecosystems | J. Bendix, M. G. Commons | 2017 | Bendix, J., and Commons, M.G., 2017, Distribution and frequency of wildfire in California riparian ecosystems: Environmental Research Letters, v. 12, no. 7, article 075008, at https://doi.org/10.1088/1748-9326/aa7087. |
The role of previous fires in the management and expenditures of subsequent large wildfires | E. J. Belval, C. D. O’Connor, M. P. Thompson, M. S. Hand | 2019 | Belval, E.J., O’Connor, C.D., Thompson, M.P., and Hand, M.S., 2019, The role of previous fires in the management and expenditures of subsequent large wildfires: Fire, v. 2, no. 4, article 57, at https://doi.org/10.3390/fire2040057. |
Tree survival scales to community-level effects following mixed-severity fire in a mixed-conifer forest | R. Travis Belote, A. J. Larson, M. S. Dietz | 2015 | Travis Belote, R., Larson, A.J., and Dietz, M.S., 2015, Tree survival scales to community-level effects following mixed-severity fire in a mixed-conifer forest: Forest Ecology and Management, v. 353, p. 221–231, at https://doi.org/10.1016/j.foreco.2015.05.033. |
Contemporary patterns of burn severity heterogeneity from fires in the northwestern U.S. | Belote, R.T. | 2015 | Belote, R.T., 2015, Contemporary patterns of burn severity heterogeneity from fires in the northwestern U.S., in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 252–256, at https://www.fs.usda.gov/treesearch/pubs/49451. |
Imputed forest structure uncertainty varies across elevational and longitudinal gradients in the western Cascade Mountains, Oregon, USA | D. M. Bell, M. J. Gregory, J. L. Ohmann | 2015 | Bell, D.M., Gregory, M.J., and Ohmann, J.L., 2015, Imputed forest structure uncertainty varies across elevational and longitudinal gradients in the western Cascade Mountains, Oregon, USA: Forest Ecology and Management, v. 358, p. 154–164, at https://doi.org/10.1016/j.foreco.2015.09.007. |
Can low-severity fire reverse compositional change in montane forests of the Sierra Nevada, California, USA? | K. M. L. Becker, J. A. Lutz | 2016 | Becker, K.M.L., and Lutz, J.A., 2016, Can low-severity fire reverse compositional change in montane forests of the Sierra Nevada, California, USA?: Ecosphere, v. 7, no. 12, article e01484, at https://doi.org/10.1002/ecs2.1484. |
The impacts and implications of an intensifying fire regime on Alaskan boreal forest composition and albedo | P. S. A. Beck, S. J. Goetz, M. C. Mack, H. D. Alexander, Y. Jin, J. T. Randerson, M. M. Loranty | 2011 | Beck, P.S.A., Goetz, S.J., Mack, M.C., Alexander, H.D., Jin, Y., Randerson, J.T., and Loranty, M.M., 2011, The impacts and implications of an intensifying fire regime on Alaskan boreal forest composition and albedo: Global Change Biology, v. 17, no. 9, p. 2853–2866, at https://doi.org/10.1111/j.1365-2486.2011.02412.x. |
Mandated vs. voluntary adaptation to natural disasters—The case of U.S. wildfires | Patrick W. Baylis , Judson Boomhower | 2021 | Baylis, P.W., and Boomhower, J., 2021, Mandated vs. voluntary adaptation to natural disasters—The case of U.S. wildfires: National Bureau of Economic Research NBER Working Paper Series, Working Paper 29621, 50 p., at https://www.nber.org/papers/w29621. |
The economics of wildfire in the United States | J. Bayham, J. K. Yoder, P. A. Champ, D. E. Calkin | 2022 | Bayham, J., Yoder, J.K., Champ, P.A., and Calkin, D.E., 2022, The economics of wildfire in the United States: Annual Review of Resource Economics, v. 14, p. 379–401, at https://doi.org/10.1146/annurev-resource-111920-014804. |
The impacts of a wildfire in a semiarid grassland on soil nematode abundances over 4 years | J. Bastow | 2020 | Bastow, J., 2020, The impacts of a wildfire in a semiarid grassland on soil nematode abundances over 4 years: Biology and Fertility of Soils, v. 56, no. 5, p. 675–685, at https://doi.org/10.1007/s00374-020-01441-4. |
BAMS—A tool for supervised burned area mapping using Landsat data | A. Bastarrika, M. Alvarado, K. Artano, M. P. Martinez, A. Mesanza, L. Torre, R. Ramo, E. Chuvieco | 2014 | Bastarrika, A., Alvarado, M., Artano, K., Martinez, M.P., Mesanza, A., Torre, L., Ramo, R., and Chuvieco, E., 2014, BAMS—A tool for supervised burned area mapping using Landsat data: Remote Sensing, v. 6, no. 12, p. 12360–12380, at https://doi.org/10.3390/rs61212360. |
Forest carbon emission sources are not equal—Putting fire, harvest, and fossil fuel emissions in context | K. J. Bartowitz, E. S. Walsh, J. E. Stenzel, C. A. Kolden, T. W. Hudiburg | 2022 | Bartowitz, K.J., Walsh, E.S., Stenzel, J.E., Kolden, C.A., and Hudiburg, T.W., 2022, Forest carbon emission sources are not equal—Putting fire, harvest, and fossil fuel emissions in context: Frontiers in Forests and Global Change, v. 5, article 867112, at https://doi.org/10.3389/ffgc.2022.867112. |
Detecting patterns of post-fire pine regeneration in a Madrean Sky Island with field surveys and remote sensing | A. M. Barton, H. M. Poulos, G. W. Koch, T. E. Kolb, A. E. Thode | 2023 | Barton, A.M., Poulos, H.M., Koch, G.W., Kolb, T.E., and Thode, A.E., 2023, Detecting patterns of post-fire pine regeneration in a Madrean Sky Island with field surveys and remote sensing: Science of the Total Environment, v. 867, article 161517, at https://doi.org/10.1016/j.scitotenv.2023.161517. |
Pine vs. oaks revisited—Conversion of Madrean pine-oak forest to oak shrubland after high-severity wildfire in the Sky Islands of Arizona | A. M. Barton, H. M. Poulos | 2018 | Barton, A.M., and Poulos, H.M., 2018, Pine vs. oaks revisited—Conversion of Madrean pine-oak forest to oak shrubland after high-severity wildfire in the Sky Islands of Arizona: Forest Ecology and Management, v. 414, p. 28–40, at https://doi.org/10.1016/j.foreco.2018.02.011. |
Wildfire and topography drive woody plant diversity in a Sky Island mountain range in the southwest USA | A. M. Barton, H. Poulos | 2021 | Barton, A.M., and Poulos, H., 2021, Wildfire and topography drive woody plant diversity in a Sky Island mountain range in the southwest USA: Ecology and Evolution, v. 11, no. 21, p. 14715–14732, at https://doi.org/10.1002/ece3.8158. |
The impact of wildfire on baseflow recession rates in California | R. R. Bart, C. L. Tague | 2017 | Bart, R.R., and Tague, C.L., 2017, The impact of wildfire on baseflow recession rates in California: Hydrological Processes, v. 31, no. 8, p. 1662–1673, at https://doi.org/10.1002/hyp.11141. |
Effects of ownership patterns on cross-boundary wildfires | A. M. G. Barros, M. A. Day, T. A. Spies, A. A. Ager | 2021 | Barros, A.M.G., Day, M.A., Spies, T.A., and Ager, A.A., 2021, Effects of ownership patterns on cross-boundary wildfires: Scientific Reports, v. 11, no. 1, article 19319, at https://doi.org/10.1038/s41598-021-98730-1. |
Spatiotemporal dynamics of simulated wildfire, forest management, and forest succession in central Oregon, USA | A. M. G. Barros, A. A. Ager, M. A. Day, H. K. Preisler, T. A. Spies, E. White, R. J. Pabst, K. A. Olsen, E. Platt, J. D. Bailey, J. P. Bolte | 2017 | Barros, A.M.G., Ager, A.A., Day, M.A., Preisler, H.K., Spies, T.A., White, E., Pabst, R.J., Olsen, K.A., Platt, E., et al., 2017, Spatiotemporal dynamics of simulated wildfire, forest management, and forest succession in central Oregon, USA: Ecology and Society, v. 22, no. 1, article 24, at https://doi.org/10.5751/ES-08917-220124. |
Improving long-term fuel treatment effectiveness in the National Forest System through quantitative prioritization | A. M. G. Barros, A. A. Ager, M. A. Day, P. Palaiologou | 2019 | Barros, A.M.G., Ager, A.A., Day, M.A., and Palaiologou, P., 2019, Improving long-term fuel treatment effectiveness in the National Forest System through quantitative prioritization: Forest Ecology and Management, v. 433, p. 514–527, at https://doi.org/10.1016/j.foreco.2018.10.041. |
Surface water quality after the Woolsey Fire in southern California | S. M. Barron, N. Mladenov, K. E. Sant, A. M. Kinoshita | 2022 | Barron, S.M., Mladenov, N., Sant, K.E., and Kinoshita, A.M., 2022, Surface water quality after the Woolsey Fire in southern California: Water, Air, and Soil Pollution, v. 233, no. 9, article 377, at https://doi.org/10.1007/s11270-022-05844-x. |
Wildfire influences individual growth and breeding dispersal, but not survival and recruitment in a montane amphibian | G. M. Barrile, A. D. Chalfoun, W. A. Estes-Zumpf, A. W. Walters | 2022 | Barrile, G.M., Chalfoun, A.D., Estes-Zumpf, W.A., and Walters, A.W., 2022, Wildfire influences individual growth and breeding dispersal, but not survival and recruitment in a montane amphibian: Ecosphere, v. 13, no. 8, article e4212, at https://doi.org/10.1002/ecs2.4212. |
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Wildfires increasingly impact western US fluvial networks | G. Ball, P. Regier, R. Gonzalez-Pinzon, J. Reale, D. Van Horn | 2021 | Ball, G., Regier, P., Gonzalez-Pinzon, R., Reale, J., and Van Horn, D., 2021, Wildfires increasingly impact western US fluvial networks: Nature Communications, v. 12, no. 1, article 2484, at https://doi.org/10.1038/s41467-021-22747-3. |
Social-environmental extremes—Rethinking extraordinary events as outcomes of interacting biophysical and social systems | J. K. Balch, V. Iglesias, A. E. Braswell, M. W. Rossi, M. B. Joseph, A. L. Mahood, T. R. Shrum, C. T. White, V. M. Scholl, B. McGuire, C. Karban, M. Buckland, W. R. Travis | 2020 | Balch, J.K., Iglesias, V., Braswell, A.E., Rossi, M.W., Joseph, M.B., Mahood, A.L., Shrum, T.R., White, C.T., Scholl, V.M., et al., 2020, Social-environmental extremes—Rethinking extraordinary events as outcomes of interacting biophysical and social systems: Earth's Future, v. 8, no. 7, article e2019EF001319, at https://doi.org/10.1029/2019ef001319. |
FIRED (Fire Events Delineation)—An open, flexible algorithm and database of US fire events derived from the MODIS Burned Area Product (2001–2019) | J. K. Balch, L. A. St. Denis, A. L. Mahood, N. P. Mietkiewicz, T. M. Williams, J. McGlinchy, M. C. Cook | 2020 | Balch, J.K., St. Denis, L.A., Mahood, A.L., Mietkiewicz, N.P., Williams, T.M., McGlinchy, J., and Cook, M.C., 2020, FIRED (Fire Events Delineation)—An open, flexible algorithm and database of US fire events derived from the MODIS Burned Area Product (2001–2019): Remote Sensing, v. 12, no. 21, article 3498, at https://doi.org/10.3390/rs12213498. |
Human-started wildfires expand the fire niche across the United States | J. K. Balch, B. A. Bradley, J. T. Abatzoglou, R. C. Nagy, E. J. Fusco, A. L. Mahood | 2017 | Balch, J.K., Bradley, B.A., Abatzoglou, J.T., Nagy, R.C., Fusco, E.J., and Mahood, A.L., 2017, Human-started wildfires expand the fire niche across the United States: Proceedings of the National Academy of Sciences of the United States of America, v. 114, no. 11, p. 2946–2951, at https://doi.org/10.1073/pnas.1617394114. |
Warming weakens the night-time barrier to global fire | J. K. Balch, J. T. Abatzoglou, M. B. Joseph, M. J. Koontz, A. L. Mahood, J. McGlinchy, M. E. Cattau, A. P. Williams | 2022 | Balch, J.K., Abatzoglou, J.T., Joseph, M.B., Koontz, M.J., Mahood, A.L., McGlinchy, J., Cattau, M.E., and Williams, A.P., 2022, Warming weakens the night-time barrier to global fire: Nature, v. 602, no. 7897, p. 442–448, at https://doi.org/10.1038/s41586-021-04325-1. |
Switching on the big burn of 2017 | J. Balch, T. Schoennagel, A. Williams, J. Abatzoglou, M. Cattau, N. Mietkiewicz, L. St. Denis | 2018 | Balch, J., Schoennagel, T., Williams, A., Abatzoglou, J., Cattau, M., Mietkiewicz, N., and St. Denis, L., 2018, Switching on the big burn of 2017: Fire, v. 1, no. 1, article 17, at https://doi.org/10.3390/fire1010017. |
Harnessing natural disturbances—A nature-based solution for restoring and adapting dry forests in the western USA to climate change | W. L. Baker, C. T. Hanson, D. A. DellaSala | 2023 | Baker, W.L., Hanson, C.T., and DellaSala, D.A., 2023, Harnessing natural disturbances—A nature-based solution for restoring and adapting dry forests in the western USA to climate change: Fire, v. 6, no. 11, article 428, at https://doi.org/10.3390/fire6110428. |
Fire-history implications of fire scarring | W. L. Baker, A. J. Dugan | 2013 | Baker, W.L., and Dugan, A.J., 2013, Fire-history implications of fire scarring: Canadian Journal of Forest Research, v. 43, no. 10, p. 951–962, at https://doi.org/10.1139/cjfr-2013-0176. |
Tree-regeneration decline and type-conversion after high-severity fires will likely cause little western USA Forest loss from climate change | W. L. Baker | 2023 | Baker, W.L., 2023, Tree-regeneration decline and type-conversion after high-severity fires will likely cause little western USA Forest loss from climate change: Climate, v. 11, no. 11, article 214, at https://doi.org/10.3390/cli11110214. |
Is climate change restoring historical fire regimes across temperate landscapes of the San Juan Mountains, Colorado, USA? | W. L. Baker | 2022 | Baker, W.L., 2022, Is climate change restoring historical fire regimes across temperate landscapes of the San Juan Mountains, Colorado, USA?: Land, v. 11, no. 10, article 1615, at https://doi.org/10.3390/land11101615. |
Transitioning western U.S. dry forests to limited committed warming with bet-hedging and natural disturbances | W. L. Baker | 2018 | Baker, W.L., 2018, Transitioning western U.S. dry forests to limited committed warming with bet-hedging and natural disturbances: Ecosphere, v. 9, no. 6, article e02288, at https://doi.org/10.1002/ecs2.2288. |
Are high-severity fires burning at much higher rates recently than historically in dry-forest landscapes of the western USA? | W. L. Baker | 2015 | Baker, W.L., 2015, Are high-severity fires burning at much higher rates recently than historically in dry-forest landscapes of the western USA?: PLoS ONE, v. 10, no. 9, article e0136147, at https://doi.org/10.1371/journal.pone.0136147. |
Historical forest structure and fire in Sierran mixed-conifer forests reconstructed from General Land Office survey data | W. L. Baker | 2014 | Baker, W.L., 2014, Historical forest structure and fire in Sierran mixed-conifer forests reconstructed from General Land Office survey data: Ecosphere, v. 5, no. 7, article 79, at https://doi.org/10.1890/ES14-00046.1. |
Is wildland fire increasing in sagebrush landscapes of the western United States? | W. L. Baker | 2013 | Baker, W.L., 2013, Is wildland fire increasing in sagebrush landscapes of the western United States?: Annals of the Association of American Geographers, v. 103, no. 1, p. 5–19, at https://doi.org/10.1080/00045608.2012.732483. |
Implications of spatially extensive historical data from surveys for restoring dry forests of Oregon's eastern Cascades | W. L. Baker | 2012 | Baker, W.L., 2012, Implications of spatially extensive historical data from surveys for restoring dry forests of Oregon's eastern Cascades: Ecosphere, v. 3, no. 3, article 23, at https://doi.org/10.1890/ES11-00320.1. |
Historical fire regimes in ponderosa pine and mixed-conifer landscapes of the San Juan Mountains, Colorado, USA, from multiple sources | W. Baker | 2018 | Baker, W., 2018, Historical fire regimes in ponderosa pine and mixed-conifer landscapes of the San Juan Mountains, Colorado, USA, from multiple sources: Fire, v. 1, no. 2, article 23, at https://doi.org/10.3390/fire1020023. |
Historical seasonal changes in prescribed burn windows in California | J. A. Baijnath-Rodino, S. Li, A. Martinez, M. Kumar, L. N. Quinn-Davidson, R. A. York, T. Banerjee | 2022 | Baijnath-Rodino, J.A., Li, S., Martinez, A., Kumar, M., Quinn-Davidson, L.N., York, R.A., and Banerjee, T., 2022, Historical seasonal changes in prescribed burn windows in California: Science of the Total Environment, v. 836, article 155723, at https://doi.org/10.1016/j.scitotenv.2022.155723. |
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California’s forest carbon offsets buffer pool is severely undercapitalized | G. Badgley, F. Chay, O. S. Chegwidden, J. J. Hamman, J. Freeman, D. Cullenward | 2022 | Badgley, G., Chay, F., Chegwidden, O.S., Hamman, J.J., Freeman, J., and Cullenward, D., 2022, California’s forest carbon offsets buffer pool is severely undercapitalized: Frontiers in Forests and Global Change, v. 5, article 930426, at https://doi.org/10.3389/ffgc.2022.930426. |
Integration of multiple spectral indices and a neural network for burned area mapping based on MODIS data | R. Ba, W. Song, X. Li, Z. Xie, S. Lo | 2019 | Ba, R., Song, W., Li, X., Xie, Z., and Lo, S., 2019, Integration of multiple spectral indices and a neural network for burned area mapping based on MODIS data: Remote Sensing, v. 11, no. 3, article 326, at https://doi.org/10.3390/rs11030326. |
Carbon emissions from the peat fire problem—A review | N. A. Che Azmi, N. Mohd Apandi, A. S. A. Rashid | 2021 | Che Azmi, N.A., Mohd Apandi, N., and A. Rashid, A.S., 2021, Carbon emissions from the peat fire problem—A review: Environmental Science and Pollution Research International, v. 28, no. 14, p. 16948–16961, at https://doi.org/10.1007/s11356-021-12886-x. |
Density-based cluster detection at multiple spatial scales via kullback-leibler divergence of reachability profiles | Aydin, O., Osorio-Murillo, C., Huang, C.-C. | 2022 | Aydin, O., Osorio-Murillo, C., and Huang, C.-C., 2022, Density-based cluster detection at multiple spatial scales via kullback-leibler divergence of reachability profiles, in GeoAI '22—Proceedings of the 5th ACM SIGSPATIAL International Workshop on AI for Geographic Knowledge Discovery, Seattle, Wash., 1–4 November 2022, Proceedings: New York, N.Y., Association for Computing Machinery, p. 66–75, at https://doi.org/10.1145/3557918.3565870. |
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Assessing wildfire burn severity indices using Sentinel-2 Data—A comparative study of common remote sensing burn indices and CBI field data | Atakul, Canan, Di, Liping | 2023 | Atakul, C., and Di, L., 2023, Assessing wildfire burn severity indices using Sentinel-2 Data—A comparative study of common remote sensing burn indices and CBI field data, in 11th International Conference on Agro-Geoinformatics, Wuhan, China, 25–28 July 2023, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 1–5, at https://doi.org/10.1109/Agro-Geoinformatics59224.2023.10233309. |
Spatial and temporal trends of drought effects in a heterogeneous semi-arid forest ecosystem | T. J. Assal, P. J. Anderson, J. Sibold | 2016 | Assal, T.J., Anderson, P.J., and Sibold, J., 2016, Spatial and temporal trends of drought effects in a heterogeneous semi-arid forest ecosystem: Forest Ecology and Management, v. 365, p. 137–151, at https://doi.org/10.1016/j.foreco.2016.01.017. |
A global wildfire dataset for the analysis of fire regimes and fire behaviour | T. Artes, D. Oom, D. de Rigo, T. H. Durrant, P. Maianti, G. Liberta, J. San-Miguel-Ayanz | 2019 | Artes, T., Oom, D., de Rigo, D., Durrant, T.H., Maianti, P., Liberta, G., and San-Miguel-Ayanz, J., 2019, A global wildfire dataset for the analysis of fire regimes and fire behaviour: Scientific Data, v. 6, no. 1, article 296, at https://doi.org/10.1038/s41597-019-0312-2. |
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Combining methods to estimate post-fire soil erosion using remote sensing data | I. Argentiero, G. F. Ricci, M. Elia, M. D'Este, V. Giannico, F. V. Ronco, F. Gentile, G. Sanesi | 2021 | Argentiero, I., Ricci, G.F., Elia, M., D'Este, M., Giannico, V., Ronco, F.V., Gentile, F., and Sanesi, G., 2021, Combining methods to estimate post-fire soil erosion using remote sensing data: Forests, v. 12, no. 8, article 1105, at https://doi.org/10.3390/f12081105. |
Northern Colorado Plateau piñon-juniper woodland decline over the past century | P. A. Arendt, W. L. Baker | 2013 | Arendt, P.A., and Baker, W.L., 2013, Northern Colorado Plateau piñon-juniper woodland decline over the past century: Ecosphere, v. 4, no. 8, article 103, at https://doi.org/10.1890/ES13-00081.1. |
Application of fractional techniques in the analysis of forest fires | M. Lopes António, J. A. T. Machado | 2016 | Lopes António, M., and Machado, J.A.T., 2016, Application of fractional techniques in the analysis of forest fires: International Journal of Nonlinear Sciences and Numerical Simulation, v. 17, no. 7-8, p. 381–390, at https://doi.org/10.1515/ijnsns-2016-0026. |
Does post-fire recovery of native grasses across abiotic-stress and invasive-grass gradients match theoretical predictions, in sagebrush steppe? | C. R. Anthony, M. J. Germino | 2023 | Anthony, C.R., and Germino, M.J., 2023, Does post-fire recovery of native grasses across abiotic-stress and invasive-grass gradients match theoretical predictions, in sagebrush steppe?: Global Ecology and Conservation, v. 42, article e02410, at https://doi.org/10.1016/j.gecco.2023.e02410. |
Predictive models of selective cattle use of large, burned landscapes in semiarid sagebrush-steppe | C. R. Anthony, M. J. Germino | 2022 | Anthony, C.R., and Germino, M.J., 2022, Predictive models of selective cattle use of large, burned landscapes in semiarid sagebrush-steppe: Rangeland Ecology & Management, v. 85, p. 1–8, at https://doi.org/10.1016/j.rama.2022.07.007. |
Fire severity unaffected by spruce beetle outbreak in spruce-fir forests in southwestern Colorado | R. A. Andrus, T. T. Veblen, B. J. Harvey, S. J. Hart | 2016 | Andrus, R.A., Veblen, T.T., Harvey, B.J., and Hart, S.J., 2016, Fire severity unaffected by spruce beetle outbreak in spruce-fir forests in southwestern Colorado: Ecological Applications, v. 26, no. 3, p. 700–11, at https://doi.org/10.1890/15-1121. |
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Spatial and temporal drivers of post-fire tree establishment and height growth in a managed forest landscape | R. A. Andrus, C. A. Droske, M. C. Franz, A. T. Hudak, L. B. Lentile, S. A. Lewis, P. Morgan, P. R. Robichaud, A. J. H. Meddens | 2022 | Andrus, R.A., Droske, C.A., Franz, M.C., Hudak, A.T., Lentile, L.B., Lewis, S.A., Morgan, P., Robichaud, P.R., and Meddens, A.J.H., 2022, Spatial and temporal drivers of post-fire tree establishment and height growth in a managed forest landscape: Fire Ecology, v. 18, no. 1, article 29, at https://doi.org/10.1186/s42408-022-00153-4. |
Wildfire Emergency Response Hazard Extraction and Analysis of Trends (HEAT) through natural language processing and time series | Andrade, Sequoia R., Walsh, Hannah S. | 2021 | Andrade, S.R., and Walsh, H.S., 2021, Wildfire Emergency Response Hazard Extraction and Analysis of Trends (HEAT) through natural language processing and time series, in 2021 IEEE/AIAA 40th Digital Avionics Systems Conference (DASC), San Antonio, Tex., 3–7 October 2021, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 1–10, at https://doi.org/10.1109/dasc52595.2021.9594501. |
Developing a set of indicators to identify, monitor, and track impacts and change in forests of the United States | S. M. Anderson, L. S. Heath, M. R. Emery, J. A. Hicke, J. S. Littell, A. Lucier, J. G. Masek, D. L. Peterson, R. Pouyat, K. M. Potter, G. Robertson, J. Sperry | 2021 | Anderson, S.M., Heath, L.S., Emery, M.R., Hicke, J.A., Littell, J.S., Lucier, A., Masek, J.G., Peterson, D.L., Pouyat, R., et al., 2021, Developing a set of indicators to identify, monitor, and track impacts and change in forests of the United States: Climatic Change, v. 165, no. 1-2, article 13, at https://doi.org/10.1007/s10584-021-02993-6. |
Inequality in agency response—Evidence from salient wildfire events | S. Anderson, A. J. Plantinga, M. Wibbenmeyer | 2023 | Anderson, S., Plantinga, A.J., and Wibbenmeyer, M., 2023, Inequality in agency response—Evidence from salient wildfire events: The Journal of Politics, v. 85, no. 2, p. 625–639, at https://doi.org/10.1086/722044. |
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Canada lynx occupancy and density in Glacier National Park | A. K. Anderson, J. S. Waller, D. H. Thornton | 2023 | Anderson, A.K., Waller, J.S., and Thornton, D.H., 2023, Canada lynx occupancy and density in Glacier National Park: The Journal of Wildlife Management, v. 87, no. 4, article e22383, at https://doi.org/10.1002/jwmg.22383. |
Climate-driven risks to the climate mitigation potential of forests | W. R. L. Anderegg, A. T. Trugman, G. Badgley, C. M. Anderson, A. Bartuska, P. Ciais, D. Cullenward, C. B. Field, J. Freeman, S. J. Goetz, J. A. Hicke, D. Huntzinger, R. B. Jackson, J. Nickerson, S. Pacala, J. T. Randerson | 2020 | Anderegg, W.R.L., Trugman, A.T., Badgley, G., Anderson, C.M., Bartuska, A., Ciais, P., Cullenward, D., Field, C.B., Freeman, J., et al., 2020, Climate-driven risks to the climate mitigation potential of forests: Science, v. 368, no. 6497, article eaaz7005, at https://doi.org/10.1126/science.aaz7005. |
Climate change greatly escalates forest disturbance risks to US property values | W. R. L. Anderegg, T. Collins, S. Grineski, S. Nicholls, C. Nolte | 2023 | Anderegg, W.R.L., Collins, T., Grineski, S., Nicholls, S., and Nolte, C., 2023, Climate change greatly escalates forest disturbance risks to US property values: Environmental Research Letters, v. 18, no. 9, article 094011, at https://doi.org/10.1088/1748-9326/ace639. |
Future climate risks from stress, insects and fire across US forests | W. R. L. Anderegg, O. S. Chegwidden, G. Badgley, A. T. Trugman, D. Cullenward, J. T. Abatzoglou, J. A. Hicke, J. Freeman, J. J. Hamman | 2022 | Anderegg, W.R.L., Chegwidden, O.S., Badgley, G., Trugman, A.T., Cullenward, D., Abatzoglou, J.T., Hicke, J.A., Freeman, J., and Hamman, J.J., 2022, Future climate risks from stress, insects and fire across US forests: Ecological Letters, v. 25, no. 6, p. 1510–1520, at https://doi.org/10.1111/ele.14018. |
The Global Fire Atlas of individual fire size, duration, speed and direction | N. Andela, D. C. Morton, L. Giglio, R. Paugam, Y. Chen, S. Hantson, G. R. Van Der Werf, J. T. Anderson | 2019 | Andela, N., Morton, D.C., Giglio, L., Paugam, R., Chen, Y., Hantson, S., Van Der Werf, G.R., and Anderson, J.T., 2019, The Global Fire Atlas of individual fire size, duration, speed and direction: Earth System Science Data, v. 11, no. 2, p. 529–552, at https://doi.org/10.5194/essd-11-529-2019. |
Extreme wildfires, distant air pollution, and household financial health | An, Xudong, Gabriel, Stuart, Tzur-Ilan, Nitzan | 2024 | An, X., Gabriel, S., and Tzur-Ilan, N., 2024, Extreme wildfires, distant air pollution, and household financial health: Philadelphia, Pa., Federal Reserve Bank Philadelphia Working Papers Research Department, WP 24-01, 60 p., at https://doi.org/10.21799/frbp.wp.2024.01. |
Land and atmosphere precursors to fuel loading, wildfire ignition and post-fire recovery | M. R. Alizadeh, J. Adamowski, D. Entekhabi | 2024 | Alizadeh, M.R., Adamowski, J., and Entekhabi, D., 2024, Land and atmosphere precursors to fuel loading, wildfire ignition and post-fire recovery: Geophysical Research Letters, v. 51, no. 2, article e2023GL105324, at https://doi.org/10.1029/2023gl105324. |
Warming enabled upslope advance in western US forest fires | M. R. Alizadeh, J. T. Abatzoglou, C. H. Luce, J. F. Adamowski, A. Farid, M. Sadegh | 2021 | Alizadeh, M.R., Abatzoglou, J.T., Luce, C.H., Adamowski, J.F., Farid, A., and Sadegh, M., 2021, Warming enabled upslope advance in western US forest fires: Proceedings of the National Academy of Sciences of the United States of America, v. 118, no. 22, article e2009717118, at https://doi.org/10.1073/pnas.2009717118. |
The relative impacts of vegetation, topography and spatial arrangement on building loss to wildfires in case studies of California and Colorado | P. M. Alexandre, S. I. Stewart, M. H. Mockrin, N. S. Keuler, A. D. Syphard, A. Bar-Massada, M. K. Clayton, V. C. Radeloff | 2016 | Alexandre, P.M., Stewart, S.I., Mockrin, M.H., Keuler, N.S., Syphard, A.D., Bar-Massada, A., Clayton, M.K., and Radeloff, V.C., 2016, The relative impacts of vegetation, topography and spatial arrangement on building loss to wildfires in case studies of California and Colorado: Landscape Ecology, v. 31, no. 2, p. 415–430, at https://doi.org/10.1007/s10980-015-0257-6. |
Factors related to building loss due to wildfires in the conterminous United States | P. M. Alexandre, S. I. Stewart, N. S. Keuler, M. K. Clayton, M. H. Mockrin, A. Bar-Massada, A. D. Syphard, V. C. Radeloff | 2016 | Alexandre, P.M., Stewart, S.I., Keuler, N.S., Clayton, M.K., Mockrin, M.H., Bar-Massada, A., Syphard, A.D., and Radeloff, V.C., 2016, Factors related to building loss due to wildfires in the conterminous United States: Ecological Applications, v. 26, no. 7, p. 2323–2338, at https://doi.org/10.1002/eap.1376. |
Rebuilding and new housing development after wildfire | P. M. Alexandre, M. H. Mockrin, S. I. Stewart, R. B. Hammer, V. C. Radeloff | 2015 | Alexandre, P.M., Mockrin, M.H., Stewart, S.I., Hammer, R.B., and Radeloff, V.C., 2015, Rebuilding and new housing development after wildfire: International Journal of Wildland Fire, v. 24, no. 1, p. 138–149, at https://doi.org/10.1071/WF13197. |
Contrasting the efficiency of landscape versus community protection fuel treatment strategies to reduce wildfire exposure and risk | F. Alcasena, A. A. Ager, P. Belavenutti, M. Krawchuk, M. A. Day | 2022 | Alcasena, F., Ager, A.A., Belavenutti, P., Krawchuk, M., and Day, M.A., 2022, Contrasting the efficiency of landscape versus community protection fuel treatment strategies to reduce wildfire exposure and risk: Journal of Environmental Management, v. 309, article 114650, at https://doi.org/10.1016/j.jenvman.2022.114650. |
Drought sensitivity and trends of riparian vegetation vigor in Nevada, USA (1985–2018) | C. M. Albano, K. C. McGwire, M. B. Hausner, D. J. McEvoy, C. G. Morton, J. L. Huntington | 2020 | Albano, C.M., McGwire, K.C., Hausner, M.B., McEvoy, D.J., Morton, C.G., and Huntington, J.L., 2020, Drought sensitivity and trends of riparian vegetation vigor in Nevada, USA (1985–2018): Remote Sensing, v. 12, no. 9, article 1362, at https://doi.org/10.3390/RS12091362. |
Influence of atmospheric rivers on vegetation productivity and fire patterns in the southwestern US | C. M. Albano, M. D. Dettinger, C. E. Soulard | 2017 | Albano, C.M., Dettinger, M.D., and Soulard, C.E., 2017, Influence of atmospheric rivers on vegetation productivity and fire patterns in the southwestern US: Journal of Geophysical Research—Biogeosciences, v. 122, no. 2, p. 308–323, at https://doi.org/10.1002/2016jg003608. |
Changes in soil properties over time after a wildfire and implications to slope stability | I. D. Akin, T. O. Akinleye, P. R. Robichaud | 2023 | Akin, I.D., Akinleye, T.O., and Robichaud, P.R., 2023, Changes in soil properties over time after a wildfire and implications to slope stability: Journal of Geotechnical and Geoenvironmental Engineering, v. 149, no. 7, article 04023045, at https://doi.org/10.1061/jggefk.Gteng-11348. |
Droughts impede water balance recovery from fires in the western United States | S. K. Ahmad, T. R. Holmes, S. V. Kumar, T. M. Lahmers, P. W. Liu, W. Nie, A. Getirana, E. Orland, R. Bindlish, A. Guzman, C. R. Hain, F. S. Melton, K. A. Locke, Y. Yang | 2024 | Ahmad, S.K., Holmes, T.R., Kumar, S.V., Lahmers, T.M., Liu, P.W., Nie, W., Getirana, A., Orland, E., Bindlish, R., et al., 2024, Droughts impede water balance recovery from fires in the western United States: Nature Ecology and Evolution, v. 8, p. 229–238, at https://doi.org/10.1038/s41559-023-02266-8. |
The race between fuels and fruits—Testing mechanisms of serotinous forest resilience to short-interval severe reburns, Final Report | Agne, M. C., Harvey, B. J. | 2022 | Agne, M.C., and Harvey, B.J., 2022, The race between fuels and fruits—Testing mechanisms of serotinous forest resilience to short-interval severe reburns, Final Report: Joint Fire Science Program JFSP PROJECT ID—19-1-01-16, 32 p., at https://nwcasc.uw.edu/wp-content/uploads/sites/23/2022/04/Agne_Harvey_JFSP_FinalReport.pdf. |
Fire interval and post-fire climate effects on serotinous forest resilience | M. C. Agne, J. B. Fontaine, N. J. Enright, B. J. Harvey | 2022 | Agne, M.C., Fontaine, J.B., Enright, N.J., and Harvey, B.J., 2022, Fire interval and post-fire climate effects on serotinous forest resilience: Fire Ecology, v. 18, no. 1, article 22, at https://doi.org/10.1186/s42408-022-00145-4. |
Rapid fuel recovery after stand-replacing fire in closed-cone pine forests and implications for short-interval severe reburns | M. C. Agne, J. B. Fontaine, N. J. Enright, S. M. Bisbing, B. J. Harvey | 2023 | Agne, M.C., Fontaine, J.B., Enright, N.J., Bisbing, S.M., and Harvey, B.J., 2023, Rapid fuel recovery after stand-replacing fire in closed-cone pine forests and implications for short-interval severe reburns: Forest Ecology and Management, v. 545, article 121263, at https://doi.org/10.1016/j.foreco.2023.121263. |
Demographic processes underpinning post-fire resilience in California closed-cone pine forests—The importance of fire interval, stand structure, and climate | M. C. Agne, J. B. Fontaine, N. J. Enright, S. M. Bisbing, B. J. Harvey | 2022 | Agne, M.C., Fontaine, J.B., Enright, N.J., Bisbing, S.M., and Harvey, B.J., 2022, Demographic processes underpinning post-fire resilience in California closed-cone pine forests—The importance of fire interval, stand structure, and climate: Plant Ecology, v. 223, p. 751–767, at https://doi.org/10.1007/s11258-022-01228-7. |
Restoration of fire in managed forests—A model to prioritize landscapes and analyze tradeoffs | A. A. Ager, N. M. Vaillant, A. McMahan | 2013 | Ager, A.A., Vaillant, N.M., and McMahan, A., 2013, Restoration of fire in managed forests—A model to prioritize landscapes and analyze tradeoffs: Ecosphere, v. 4, no. 2, article 29, at https://doi.org/10.1890/ES13-00007.1. |
Assessing transboundary wildfire exposure in the southwestern United States | A. A. Ager, P. Palaiologou, C. R. Evers, M. A. Day, A. M. G. Barros | 2018 | Ager, A.A., Palaiologou, P., Evers, C.R., Day, M.A., and Barros, A.M.G., 2018, Assessing transboundary wildfire exposure in the southwestern United States: Risk Analysis, v. 38, no. 10, p. 2105–2127, at https://doi.org/10.1111/risa.12999. |
Tradeoffs between US national forest harvest targets and fuel management to reduce wildfire transmission to the wildland urban interface | A. A. Ager, R. M. Houtman, M. A. Day, C. Ringo, P. Palaiologou | 2019 | Ager, A.A., Houtman, R.M., Day, M.A., Ringo, C., and Palaiologou, P., 2019, Tradeoffs between US national forest harvest targets and fuel management to reduce wildfire transmission to the wildland urban interface: Forest Ecology and Management, v. 434, p. 99–109, at https://doi.org/10.1016/j.foreco.2018.12.003. |
Planning for future fire—Scenario analysis of an accelerated fuel reduction plan for the western United States | A. A. Ager, C. R. Evers, M. A. Day, F. J. Alcasena, R. Houtman | 2021a | Ager, A.A., Evers, C.R., Day, M.A., Alcasena, F.J., and Houtman, R., 2021a, Planning for future fire—Scenario analysis of an accelerated fuel reduction plan for the western United States: Landscape and Urban Planning, v. 215, article 104212, at https://doi.org/10.1016/j.landurbplan.2021.104212. |
Predicting paradise—Modeling future wildfire disasters in the western US | A. A. Ager, M. A. Day, F. J. Alcasena, C. R. Evers, K. C. Short, I. Grenfell | 2021b | Ager, A.A., Day, M.A., Alcasena, F.J., Evers, C.R., Short, K.C., and Grenfell, I., 2021b, Predicting paradise—Modeling future wildfire disasters in the western US: Science of the Total Environment, v. 784, article 147057, at https://doi.org/10.1016/j.scitotenv.2021.147057. |
Analyzing fine-scale spatiotemporal drivers of wildfire in a forest landscape model | A. A. Ager, A. M. G. Barros, M. A. Day, H. K. Preisler, T. A. Spies, J. Bolte | 2018 | Ager, A.A., Barros, A.M.G., Day, M.A., Preisler, H.K., Spies, T.A., and Bolte, J., 2018, Analyzing fine-scale spatiotemporal drivers of wildfire in a forest landscape model: Ecological Modelling, v. 384, p. 87–102, at https://doi.org/10.1016/j.ecolmodel.2018.06.018. |
Contrasting effects of future wildfire and forest management scenarios on a fire excluded western US landscape | A. A. Ager, A. M. G. Barros, M. A. Day | 2022 | Ager, A.A., Barros, A.M.G., and Day, M.A., 2022, Contrasting effects of future wildfire and forest management scenarios on a fire excluded western US landscape: Landscape Ecology, v. 37, no. 4, p. 1091–1112, at https://doi.org/10.1007/s10980-022-01414-y. |
Model-assisted domain estimation of postfire tree regeneration in the western US using nearest neighbor techniques | D. L. R. Affleck, G. C. Gaines | 2023 | Affleck, D.L.R., and Gaines, G.C., 2023, Model-assisted domain estimation of postfire tree regeneration in the western US using nearest neighbor techniques: Canadian Journal of Forest Research, v. 53, no. 12, p. 981–995, at https://doi.org/10.1139/cjfr-2023-0007. |
Soil carbon pools and fluxes vary across a burn severity gradient three years after wildfire in Sierra Nevada mixed-conifer forest | J. Adkins, J. Sanderman, J. Miesel | 2019 | Adkins, J., Sanderman, J., and Miesel, J., 2019, Soil carbon pools and fluxes vary across a burn severity gradient three years after wildfire in Sierra Nevada mixed-conifer forest: Geoderma, v. 333, p. 10–22, at https://doi.org/10.1016/j.geoderma.2018.07.009. |
Copiotrophic bacterial traits increase with burn severity one year after a wildfire | J. Adkins, K. M. Docherty, J. R. Miesel | 2022 | Adkins, J., Docherty, K.M., and Miesel, J.R., 2022, Copiotrophic bacterial traits increase with burn severity one year after a wildfire: Frontiers in Forests and Global Change, v. 5, article 873527, at https://doi.org/10.3389/ffgc.2022.873527. |
How do soil microbial communities respond to fire in the intermediate term? Investigating direct and indirect effects associated with fire occurrence and burn severity | J. Adkins, K. M. Docherty, J. L. M. Gutknecht, J. R. Miesel | 2020 | Adkins, J., Docherty, K.M., Gutknecht, J.L.M., and Miesel, J.R., 2020, How do soil microbial communities respond to fire in the intermediate term? Investigating direct and indirect effects associated with fire occurrence and burn severity: Science of the Total Environment, v. 745, article 140957, at https://doi.org/10.1016/j.scitotenv.2020.140957. |
Fire?produced coarse woody debris and its role in sediment storage on hillslopes | K. V. Adams, J. L. Dixon, A. C. Wilcox, D. McWethy | 2023 | Adams, K.V., Dixon, J.L., Wilcox, A.C., and McWethy, D., 2023, Fire?produced coarse woody debris and its role in sediment storage on hillslopes: Earth Surface Processes and Landforms, v. 48, no. 9, p. 1665–1678, at https://doi.org/10.1002/esp.5573. |
Asymmetric hillslope erosion following wildfire in Fourmile Canyon, Colorado | E. R. Abrahams, J. M. Kaste, W. Ouimet, D. P. Dethier | 2018 | Abrahams, E.R., Kaste, J.M., Ouimet, W., and Dethier, D.P., 2018, Asymmetric hillslope erosion following wildfire in Fourmile Canyon, Colorado: Earth Surface Processes and Landforms, v. 43, no. 9, p. 2009–2021, at https://doi.org/10.1002/esp.4348. |
Winter and spring climate explains a large portion of interannual variability and trend in western US summer fire burned area | R. Abolafia-Rosenzweig, C. L. He, F. Chen | 2022 | Abolafia-Rosenzweig, R., He, C.L., and Chen, F., 2022, Winter and spring climate explains a large portion of interannual variability and trend in western US summer fire burned area: Environmental Research Letters, v. 17, no. 5, article 054030, at https://doi.org/10.1088/1748-9326/ac6886. |
Impact of anthropogenic climate change on wildfire across western US forests | J. T. Abatzoglou, A. P. Williams | 2016 | Abatzoglou, J.T., and Williams, A.P., 2016, Impact of anthropogenic climate change on wildfire across western US forests: Proceedings of the National Academy of Sciences of the United States of America, v. 113, no. 42, p. 11770–11775, at https://doi.org/10.1073/pnas.1607171113. |
Climatic influences on interannual variability in regional burn severity across western US forests | J. T. Abatzoglou, C. A. Kolden, A. P. Williams, J. A. Lutz, A. M. S. Smith | 2017 | Abatzoglou, J.T., Kolden, C.A., Williams, A.P., Lutz, J.A., and Smith, A.M.S., 2017, Climatic influences on interannual variability in regional burn severity across western US forests: International Journal of Wildland Fire, v. 26, no. 4, p. 269–275, at https://doi.org/10.1071/WF16165. |
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Increasing synchronous fire danger in forests of the western United States | J. T. Abatzoglou, C. S. Juang, A. P. Williams, C. A. Kolden, A. L. Westerling | 2021 | Abatzoglou, J.T., Juang, C.S., Williams, A.P., Kolden, C.A., and Westerling, A.L., 2021, Increasing synchronous fire danger in forests of the western United States: Geophysical Research Letters, v. 48, no. 2, article e2020GL091377, at https://doi.org/10.1029/2020GL091377. |
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Increasing large wildfires over the western United States linked to diminishing sea ice in the Arctic | Y. Zou, P. J. Rasch, H. Wang, Z. Xie, R. Zhang | 2021 | Zou, Y., Rasch, P.J., Wang, H., Xie, Z., and Zhang, R., 2021, Increasing large wildfires over the western United States linked to diminishing sea ice in the Arctic: Nature Communications, v. 12, no. 1, article 6048, at https://doi.org/10.1038/s41467-021-26232-9. |
Quantifying contributions of natural variability and anthropogenic forcings on increased fire weather risk over the western United States | Y. Zhuang, R. Fu, B. D. Santer, R. E. Dickinson, A. Hall | 2021 | Zhuang, Y., Fu, R., Santer, B.D., Dickinson, R.E., and Hall, A., 2021, Quantifying contributions of natural variability and anthropogenic forcings on increased fire weather risk over the western United States: Proceedings of the National Academy of Sciences of the United States of America, v. 118, no. 45, article e2111875118, at https://doi.org/10.1073/pnas.2111875118. |
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Monitoring landscape dynamics in central U.S. grasslands with harmonized Landsat-8 and Sentinel-2 time series data | Q. Zhou, J. Rover, J. Brown, B. Worstell, D. Howard, Z. Wu, A. L. Gallant, B. Rundquist, M. Burke | 2019 | Zhou, Q., Rover, J., Brown, J., Worstell, B., Howard, D., Wu, Z., Gallant, A.L., Rundquist, B., and Burke, M., 2019, Monitoring landscape dynamics in central U.S. grasslands with harmonized Landsat-8 and Sentinel-2 time series data: Remote Sensing, v. 11, no. 3, article 328, at https://doi.org/10.3390/rs11030328. |
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Synoptic weather patterns for large wildfires in the northwestern United States—A climatological analysis using three classification methods | S. Zhong, L. Yu, W. E. Heilman, X. Bian, H. Fromm | 2020 | Zhong, S., Yu, L., Heilman, W.E., Bian, X., and Fromm, H., 2020, Synoptic weather patterns for large wildfires in the northwestern United States—A climatological analysis using three classification methods: Theoretical and Applied Climatology, v. 141, no. 3-4, p. 1057–1073, at https://doi.org/10.1007/s00704-020-03235-y. |
A new burn severity index based on land surface temperature and enhanced vegetation index | Z. Zheng, Y. Zeng, S. Li, W. Huang | 2016 | Zheng, Z., Zeng, Y., Li, S., and Huang, W., 2016, A new burn severity index based on land surface temperature and enhanced vegetation index: International Journal of Applied Earth Observation and Geoinformation, v. 45, p. 84–94, at https://doi.org/10.1016/j.jag.2015.11.002. |
Forest fire spread simulating model using cellular automaton with extreme learning machine | Z. Zheng, W. Huang, S. Li, Y. Zeng | 2017 | Zheng, Z., Huang, W., Li, S., and Zeng, Y., 2017, Forest fire spread simulating model using cellular automaton with extreme learning machine: Ecological Modelling, v. 348, p. 33–43, at https://doi.org/10.1016/j.ecolmodel.2016.12.022. |
Forest carbon dynamics associated with growth and disturbances in Oklahoma and Texas, 1992–2006 | D. Zheng, L. S. Heath, M. J. Ducey, J. E. Smith | 2013 | Zheng, D., Heath, L.S., Ducey, M.J., and Smith, J.E., 2013, Forest carbon dynamics associated with growth and disturbances in Oklahoma and Texas, 1992–2006: Southern Journal of Applied Forestry, v. 37, no. 4, p. 216–225, at https://doi.org/10.5849/sjaf.12-028. |
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Assessing double counting of carbon emissions between forest land-cover change and forest wildfires—A case study in the United States, 1992–2006 | D. Zheng, L. S. Heath, M. J. Ducey, B. Quayle | 2013 | Zheng, D., Heath, L.S., Ducey, M.J., and Quayle, B., 2013, Assessing double counting of carbon emissions between forest land-cover change and forest wildfires—A case study in the United States, 1992–2006: Ecosystems, v. 16, no. 2, p. 310–322, at https://doi.org/10.1007/s10021-012-9616-1. |
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Comparing historical and current wildfire regimes in the Northern Rocky Mountains using a landscape succession model | F. Zhao, R. Keane, Z. Zhu, C. Huang | 2015 | Zhao, F., Keane, R., Zhu, Z., and Huang, C., 2015, Comparing historical and current wildfire regimes in the Northern Rocky Mountains using a landscape succession model: Forest Ecology and Management, v. 343, p. 9–21, at https://doi.org/10.1016/j.foreco.2015.01.020. |
Use of vegetation change tracker and support vector machine to map disturbance types in Greater Yellowstone ecosystems in a 1984–2010 Landsat time series | F. Zhao, C. Q. Huang, Z. L. Zhu | 2015 | Zhao, F., Huang, C.Q., and Zhu, Z.L., 2015, Use of vegetation change tracker and support vector machine to map disturbance types in Greater Yellowstone ecosystems in a 1984–2010 Landsat time series: IEEE Geoscience and Remote Sensing Letters, v. 12, no. 8, p. 1650–1654, at https://doi.org/10.1109/lgrs.2015.2418159. |
Biophysical feedback of forest canopy height on land surface temperature over contiguous United States | Z. Zhang, X. Li, H. Liu | 2021 | Zhang, Z., Li, X., and Liu, H., 2021, Biophysical feedback of forest canopy height on land surface temperature over contiguous United States: Environmental Research Letters, v. 17, no. 3, article 034002, at https://doi.org/10.1088/1748-9326/ac4657. |
Land cover change-induced decline in terrestrial gross primary production over the conterminous United States from 2001 to 2016 | Y. Zhang, C. Song, T. Hwang, K. Novick, J. W. Coulston, J. Vose, M. P. Dannenberg, C. R. Hakkenberg, J. Mao, C. E. Woodcock | 2021 | Zhang, Y., Song, C., Hwang, T., Novick, K., Coulston, J.W., Vose, J., Dannenberg, M.P., Hakkenberg, C.R., Mao, J., and Woodcock, C.E., 2021, Land cover change-induced decline in terrestrial gross primary production over the conterminous United States from 2001 to 2016: Agricultural and Forest Meteorology, v. 308-309, article 108609, at https://doi.org/10.1016/j.agrformet.2021.108609. |
Interannual variation in biomass burning and fire seasonality derived from geostationary satellite data across the contiguous United States from 1995 to 2011 | X. Zhang, S. Kondragunta, D. P. Roy | 2014 | Zhang, X., Kondragunta, S., and Roy, D.P., 2014, Interannual variation in biomass burning and fire seasonality derived from geostationary satellite data across the contiguous United States from 1995 to 2011: Journal of Geophysical Research—Biogeosciences, v. 119, no. 6, article 2013JG002518, at https://doi.org/10.1002/2013JG002518. |
Estimation of biomass burned areas using multiple-satellite-observed active fires | X. Zhang, S. Kondragunta, B. Quayle | 2011 | Zhang, X., Kondragunta, S., and Quayle, B., 2011, Estimation of biomass burned areas using multiple-satellite-observed active fires: IEEE Transactions on Geoscience and Remote Sensing, v. 49, no. 11, pt. 2, p. 4469–4482, at https://doi.org/10.1109/TGRS.2011.2149535. |
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Comparison of the higher-severity fire regime in historical (A.D. 1800s) and modern (A.D. 1984–2009) montane forests across 624,156 ha of the Colorado Front Range | M. A. Williams, W. L. Baker | 2012 | Williams, M.A., and Baker, W.L., 2012, Comparison of the higher-severity fire regime in historical (A.D. 1800s) and modern (A.D. 1984–2009) montane forests across 624,156 ha of the Colorado Front Range: Ecosystems, v. 15, no. 5, p. 832–847, at https://doi.org/10.1007/s10021-012-9549-8. |
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Mapping suitable Lewis's woodpecker nesting habitat in a post-fire landscape | J. C. Vogeler, Z. Yang, W. B. Cohen | 2016 | Vogeler, J.C., Yang, Z., and Cohen, W.B., 2016, Mapping suitable Lewis's woodpecker nesting habitat in a post-fire landscape: Northwest Science, v. 90, no. 4, p. 421–432, at https://doi.org/10.3955/046.090.0404. |
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Contemporary fire regimes provide a critical perspective on restoration needs in the Mexico-United States borderlands | M. L. Villarreal, J. M. Iniguez, A. D. Flesch, J. S. Sanderlin, C. Cortés Montaño, C. R. Conrad, S. L. Haire | 2020 | Villarreal, M.L., Iniguez, J.M., Flesch, A.D., Sanderlin, J.S., Cortés Montaño, C., Conrad, C.R., and Haire, S.L., 2020, Contemporary fire regimes provide a critical perspective on restoration needs in the Mexico-United States borderlands: Air, Soil and Water Research, v. 13, p. 1–18, at https://doi.org/10.1177/1178622120969191. |
Distant neighbors—Recent wildfire patterns of the Madrean Sky Islands of southwestern United States and northwestern Mexico | M. L. Villarreal, S. L. Haire, J. M. Iniguez, C. C. Montano, T. B. Poitras | 2019 | Villarreal, M.L., Haire, S.L., Iniguez, J.M., Montano, C.C., and Poitras, T.B., 2019, Distant neighbors—Recent wildfire patterns of the Madrean Sky Islands of southwestern United States and northwestern Mexico: Fire Ecology, v. 15, no. 1, article 2, at https://doi.org/10.1186/s42408-018-0012-x. |
Characterizing ground and surface fuels across Sierra Nevada forests shortly after the 2012–2016 drought | E. Vilanova, L. A. Mortenson, L. E. Cox, B. M. Bulaon, J. M. Lydersen, C. J. Fettig, J. J. Battles, J. N. Axelson | 2023 | Vilanova, E., Mortenson, L.A., Cox, L.E., Bulaon, B.M., Lydersen, J.M., Fettig, C.J., Battles, J.J., and Axelson, J.N., 2023, Characterizing ground and surface fuels across Sierra Nevada forests shortly after the 2012–2016 drought: Forest Ecology and Management, v. 537, article 120945, at https://doi.org/10.1016/j.foreco.2023.120945. |
Daily burned area and carbon emissions from boreal fires in Alaska | S. Veraverbeke, B. M. Rogers, J. T. Randerson | 2015 | Veraverbeke, S., Rogers, B.M., and Randerson, J.T., 2015, Daily burned area and carbon emissions from boreal fires in Alaska: Biogeosciences, v. 12, no. 11, p. 3579–3601, at https://doi.org/10.5194/bg-12-3579-2015. |
Evaluating spectral indices and spectral mixture analysis for assessing fire severity, combustion completeness and carbon emissions | S. Veraverbeke, S. J. Hook | 2013 | Veraverbeke, S., and Hook, S.J., 2013, Evaluating spectral indices and spectral mixture analysis for assessing fire severity, combustion completeness and carbon emissions: International Journal of Wildland Fire, v. 22, no. 5, p. 707–720, at https://doi.org/10.1071/WF12168. |
Carbon credit possibilities and economic implications of fuel reduction treatments | T. Vegh, C.-H. Huang, A. Finkral | 2013 | Vegh, T., Huang, C.-H., and Finkral, A., 2013, Carbon credit possibilities and economic implications of fuel reduction treatments: Western Journal of Applied Forestry, v. 28, no. 2, p. 57–65, at https://doi.org/10.5849/wjaf.12-006. |
Environmental change, shifting distributions, and habitat conservation plans—A case study of the California gnatcatcher | H. L. Hulton VanTassel, M. D. Bell, J. Rotenberry, R. Johnson, M. F. Allen | 2017 | Hulton VanTassel, H.L., Bell, M.D., Rotenberry, J., Johnson, R., and Allen, M.F., 2017, Environmental change, shifting distributions, and habitat conservation plans—A case study of the California gnatcatcher: Ecology and Evolution, v. 7, no. 23, p. 10326–10338, at https://doi.org/10.1002/ece3.3482. |
Persistence of MODIS evapotranspiration impacts from mountain pine beetle outbreaks in lodgepole pine forests, south-central Rocky Mountains | M. K. Vanderhoof, C. A. Williams | 2015 | Vanderhoof, M.K., and Williams, C.A., 2015, Persistence of MODIS evapotranspiration impacts from mountain pine beetle outbreaks in lodgepole pine forests, south-central Rocky Mountains: Agricultural and Forest Meteorology, v. 200, p. 78–91, at https://doi.org/10.1016/j.agrformet.2014.09.015. |
Contemporary (1984–2020) fire history metrics for the conterminous United States and ecoregional differences by land ownership | M. K. Vanderhoof, T. J. Hawbaker, C. Teske, J. Noble, J. Smith | 2022 | Vanderhoof, M.K., Hawbaker, T.J., Teske, C., Noble, J., and Smith, J., 2022, Contemporary (1984–2020) fire history metrics for the conterminous United States and ecoregional differences by land ownership: International Journal of Wildland Fire, v. 31, no. 12, p. 1167–1183, at https://doi.org/10.1071/WF22044. |
Mapping wetland burned area from Sentinel-2 across the southeastern United States and its contributions relative to Landsat-8 (2016–2019) | M. K. Vanderhoof, T. J. Hawbaker, C. Teske, A. Ku, J. Noble, J. Picotte | 2021 | Vanderhoof, M.K., Hawbaker, T.J., Teske, C., Ku, A., Noble, J., and Picotte, J., 2021, Mapping wetland burned area from Sentinel-2 across the southeastern United States and its contributions relative to Landsat-8 (2016–2019): Fire, v. 4, no. 3, article 52, at https://doi.org/10.3390/fire4030052. |
Validation of the USGS Landsat Burned Area Essential Climate Variable (BAECV) across the conterminous United States | M. K. Vanderhoof, N. Fairaux, Y.-J. G. Beal, T. J. Hawbaker | 2017 | Vanderhoof, M.K., Fairaux, N., Beal, Y.-J.G., and Hawbaker, T.J., 2017, Validation of the USGS Landsat Burned Area Essential Climate Variable (BAECV) across the conterminous United States: Remote Sensing of Environment, v. 198, p. 393–406, at https://doi.org/10.1016/j.rse.2017.06.025. |
Time series of high-resolution images enhances efforts to monitor post-fire condition and recovery, Waldo Canyon fire, Colorado, USA | M. K. Vanderhoof, C. Burt, T. J. Hawbaker | 2018 | Vanderhoof, M.K., Burt, C., and Hawbaker, T.J., 2018, Time series of high-resolution images enhances efforts to monitor post-fire condition and recovery, Waldo Canyon fire, Colorado, USA: International Journal of Wildland Fire, v. 27, no. 10, p. 699–713, at https://doi.org/10.1071/Wf17177. |
Albedo-induced radiative forcing from mountain pine beetle outbreaks in forests, south-central Rocky Mountains—Magnitude, persistence, and relation to outbreak severity | M. Vanderhoof, C. A. Williams, Y. Shuai, D. Jarvis, D. Kulakowski, J. Masek | 2014 | Vanderhoof, M., Williams, C.A., Shuai, Y., Jarvis, D., Kulakowski, D., and Masek, J., 2014, Albedo-induced radiative forcing from mountain pine beetle outbreaks in forests, south-central Rocky Mountains—Magnitude, persistence, and relation to outbreak severity: Biogeosciences, v. 11, no. 3, p. 563–575, at https://doi.org/10.5194/bg-11-563-2014. |
Impact of mountain pine beetle outbreaks on forest albedo and radiative forcing, as derived from Moderate Resolution Imaging Spectroradiometer, Rocky Mountains, USA | M. Vanderhoof, C. A. Williams, B. Ghimire, J. Rogan | 2013 | Vanderhoof, M., Williams, C.A., Ghimire, B., and Rogan, J., 2013, Impact of mountain pine beetle outbreaks on forest albedo and radiative forcing, as derived from Moderate Resolution Imaging Spectroradiometer, Rocky Mountains, USA: Journal of Geophysical Research—Biogeosciences, v. 118, no. 4, p. 1461–1471, at https://doi.org/10.1002/jgrg.20120. |
Evaluation of the U.S. Geological Survey Landsat Burned Area Essential Climate Variable across the conterminous U.S. using commercial high-resolution imagery | K. M. Vanderhoof, N. Brunner, G. Y.-J. Beal, J. T. Hawbaker | 2017 | Vanderhoof, K.M., Brunner, N., Beal, G.Y.-J., and Hawbaker, J.T., 2017, Evaluation of the U.S. Geological Survey Landsat Burned Area Essential Climate Variable across the conterminous U.S. using commercial high-resolution imagery: Remote Sensing, v. 9, no. 7, article 743, at https://doi.org/10.3390/rs9070743. |
An evaluation of the forest service hazardous fuels treatment program—Are we treating enough to promote resiliency or reduce hazard? | N. M. Vaillant, E. D. Reinhardt | 2017 | Vaillant, N.M., and Reinhardt, E.D., 2017, An evaluation of the forest service hazardous fuels treatment program—Are we treating enough to promote resiliency or reduce hazard?: Journal of Forestry, v. 115, no. 4, p. 300–308, at https://doi.org/10.5849/jof.16-067. |
Assessing landscape vulnerability to wildfire in the USA | N. M. Vaillant, C. A. Kolden, A. M. S. Smith | 2016 | Vaillant, N.M., Kolden, C.A., and Smith, A.M.S., 2016, Assessing landscape vulnerability to wildfire in the USA: Current Forestry Reports, v. 2, no. 3, p. 201–213, at https://doi.org/10.1007/s40725-016-0040-1. |
Developing an online tool for identifying at-risk populations to wildfire smoke hazards | A. Vaidyanathan, F. Yip, P. Garbe | 2018 | Vaidyanathan, A., Yip, F., and Garbe, P., 2018, Developing an online tool for identifying at-risk populations to wildfire smoke hazards: Science of the Total Environment, v. 619–620, p. 376–383, at https://doi.org/10.1016/j.scitotenv.2017.10.270. |
Evidence of widespread topoclimatic limitation for lower treelines of the Intermountain West, United States | A. K. Urza, P. J. Weisberg, T. Dilts | 2020 | Urza, A.K., Weisberg, P.J., and Dilts, T., 2020, Evidence of widespread topoclimatic limitation for lower treelines of the Intermountain West, United States: Ecological Applications, v. 30, no. 7, article e02158, at https://doi.org/10.1002/eap.2158. |
Contiguous United States wildland fire emission estimates during 2003–2015 | S. P. Urbanski, M. C. Reeves, R. E. Corley, R. P. Silverstein, W. M. Hao | 2018 | Urbanski, S.P., Reeves, M.C., Corley, R.E., Silverstein, R.P., and Hao, W.M., 2018, Contiguous United States wildland fire emission estimates during 2003–2015: Earth System Science Data, v. 10, no. 4, p. 2241–2274, at https://doi.org/10.5194/essd-10-2241-2018. |
The Wildland Fire Emission Inventory—Western United States emission estimates and an evaluation of uncertainty | S. P. Urbanski, W. M. Hao, B. Nordgren | 2011 | Urbanski, S.P., Hao, W.M., and Nordgren, B., 2011, The Wildland Fire Emission Inventory—Western United States emission estimates and an evaluation of uncertainty: Atmospheric Chemistry and Physics, v. 11, no. 24, p. 12973–13000, at https://doi.org/10.5194/acp-11-12973-2011. |
Combustion efficiency and emission factors for wildfire-season fires in mixed conifer forests of the Northern Rocky Mountains, US | S. P. Urbanski | 2013 | Urbanski, S.P., 2013, Combustion efficiency and emission factors for wildfire-season fires in mixed conifer forests of the Northern Rocky Mountains, US: Atmospheric Chemistry and Physics, v. 13, no. 14, p. 7241–7262, at https://doi.org/10.5194/acp-13-7241-2013. |
A VIIRS direct broadcast algorithm for rapid response mapping of wildfire burned area in the western United States | S. Urbanski, B. Nordgren, C. Albury, B. Schwert, D. Peterson, B. Quayle, W. M. Hao | 2018 | Urbanski, S., Nordgren, B., Albury, C., Schwert, B., Peterson, D., Quayle, B., and Hao, W.M., 2018, A VIIRS direct broadcast algorithm for rapid response mapping of wildfire burned area in the western United States: Remote Sensing of Environment, v. 219, p. 271–283, at https://doi.org/10.1016/j.rse.2018.10.007. |
Effects of invasive plants on fire regimes and postfire vegetation diversity in an arid ecosystem | E. C. Underwood, R. C. Klinger, M. L. Brooks | 2019 | Underwood, E.C., Klinger, R.C., and Brooks, M.L., 2019, Effects of invasive plants on fire regimes and postfire vegetation diversity in an arid ecosystem: Ecology and Evolution, v. 9, no. 22, p. 12421–12435, at https://doi.org/10.1002/ece3.5650. |
The post-wildfire impact of burn severity and age on black carbon snow deposition and implications for snow water resources, Cascade Range, Washington | T. M. Uecker, S. D. Kaspari, K. N. Musselman, S. McKenzie Skiles | 2020 | Uecker, T.M., Kaspari, S.D., Musselman, K.N., and McKenzie Skiles, S., 2020, The post-wildfire impact of burn severity and age on black carbon snow deposition and implications for snow water resources, Cascade Range, Washington: Journal of Hydrometeorology, v. 21, no. 8, p. 1777–1792, at https://doi.org/10.1175/JHM-D-20-0010.1. |
Wildfire immediately reduces nest and adult survival of greater sage-grouse | E. A. Tyrrell, P. S. Coates, B. G. Prochazka, B. E. Brussee, S. P. Espinosa, J. M. Hull | 2023 | Tyrrell, E.A., Coates, P.S., Prochazka, B.G., Brussee, B.E., Espinosa, S.P., and Hull, J.M., 2023, Wildfire immediately reduces nest and adult survival of greater sage-grouse: Scientific Reports, v. 13, no. 1, article 10970, at https://doi.org/10.1038/s41598-023-32937-2. |
Overlapping outbreaks of multiple bark beetle species are rarely more severe than single-species outbreaks | N. J. Tutland, K. C. Rodman, R. A. Andrus, S. J. Hart | 2023 | Tutland, N.J., Rodman, K.C., Andrus, R.A., and Hart, S.J., 2023, Overlapping outbreaks of multiple bark beetle species are rarely more severe than single-species outbreaks: Ecosphere, v. 14, no. 3, article e4478, at https://doi.org/10.1002/ecs2.4478. |
Twenty-four years after the Yellowstone Fires—Are postfire lodgepole pine stands converging in structure and function? | M. G. Turner, T. G. Whitby, D. B. Tinker, W. H. Romme | 2016 | Turner, M.G., Whitby, T.G., Tinker, D.B., and Romme, W.H., 2016, Twenty-four years after the Yellowstone Fires—Are postfire lodgepole pine stands converging in structure and function?: Ecology, v. 97, no. 5, p. 1260–73, at https://doi.org/10.1890/15-1585.1. |
The magnitude, direction, and tempo of forest change in Greater Yellowstone in a warmer world with more fire | M. G. Turner, K. H. Braziunas, W. D. Hansen, T. J. Hoecker, W. Rammer, Z. Ratajczak, A. L. Westerling, R. Seidl | 2022 | Turner, M.G., Braziunas, K.H., Hansen, W.D., Hoecker, T.J., Rammer, W., Ratajczak, Z., Westerling, A.L., and Seidl, R., 2022, The magnitude, direction, and tempo of forest change in Greater Yellowstone in a warmer world with more fire: Ecological Monographs, v. 92, no. 1, article e1485, at https://doi.org/10.1002/ecm.1485. |
Decadal trends in net ecosystem production and net ecosystem carbon balance for a regional socioecological system | D. P. Turner, W. D. Ritts, Z. Yang, R. E. Kennedy, W. B. Cohen, M. V. Duane, P. E. Thornton, B. E. Law | 2011 | Turner, D.P., Ritts, W.D., Yang, Z., Kennedy, R.E., Cohen, W.B., Duane, M.V., Thornton, P.E., and Law, B.E., 2011, Decadal trends in net ecosystem production and net ecosystem carbon balance for a regional socioecological system: Forest Ecology and Management, v. 262, no. 7, p. 1318–1325, at https://doi.org/10.1016/j.foreco.2011.06.034. |
Regional carbon cycle responses to 25 years of variation in climate and disturbance in the US Pacific Northwest | D. P. Turner, W. D. Ritts, R. E. Kennedy, A. N. Gray, Z. Q. Yang | 2016 | Turner, D.P., Ritts, W.D., Kennedy, R.E., Gray, A.N., and Yang, Z.Q., 2016, Regional carbon cycle responses to 25 years of variation in climate and disturbance in the US Pacific Northwest: Regional Environmental Change, v. 16, no. 8, p. 2345–2355, at https://doi.org/10.1007/s10113-016-0956-9. |
Effects of harvest, fire, and pest/pathogen disturbances on the West Cascades ecoregion carbon balance | D. P. Turner, W. D. Ritts, R. E. Kennedy, A. N. Gray, Z. Yang | 2015 | Turner, D.P., Ritts, W.D., Kennedy, R.E., Gray, A.N., and Yang, Z., 2015, Effects of harvest, fire, and pest/pathogen disturbances on the West Cascades ecoregion carbon balance: Carbon Balance and Management, v. 10, no. 1, article 12, at https://doi.org/10.1186/s13021-015-0022-9. |
Anthropogenic climate change impacts exacerbate summer forest fires in California | M. Turco, J. T. Abatzoglou, S. Herrera, Y. Zhuang, S. Jerez, D. D. Lucas, A. AghaKouchak, I. Cvijanovic | 2023 | Turco, M., Abatzoglou, J.T., Herrera, S., Zhuang, Y., Jerez, S., Lucas, D.D., AghaKouchak, A., and Cvijanovic, I., 2023, Anthropogenic climate change impacts exacerbate summer forest fires in California: Proceedings of the National Academy of Sciences of the United States of America, v. 120, no. 25, article e2213815120, at https://doi.org/10.1073/pnas.2213815120. |
Groundwater from perennial springs provide refuge from wildfire impacts in mountainous semiarid watershed | L. M. Tsinnajinnie, M. D. Frisbee, J. L. Wilson | 2021 | Tsinnajinnie, L.M., Frisbee, M.D., and Wilson, J.L., 2021, Groundwater from perennial springs provide refuge from wildfire impacts in mountainous semiarid watershed: Journal of Hydrology, v. 596, article 125701, at https://doi.org/10.1016/j.jhydrol.2020.125701. |
Using climate projections to assess ecosystem vulnerability at scales relevant to managers | F. J. Triepke, E. H. Muldavin, M. Wahlberg | 2019 | Triepke, F.J., Muldavin, E.H., and Wahlberg, M., 2019, Using climate projections to assess ecosystem vulnerability at scales relevant to managers: Ecosphere, v. 10, no. 9, article e02854, at https://doi.org/10.1002/ecs2.2854. |
Vegetation-Rainfall interactions reveal how climate variability and climate change alter spatial patterns of wildland fire probability on Big Island, Hawaii | C. Trauernicht | 2018 | Trauernicht, C., 2018, Vegetation-Rainfall interactions reveal how climate variability and climate change alter spatial patterns of wildland fire probability on Big Island, Hawaii: Science of the Total Environment, v. 650, pt. 1, p. 459–469, at https://doi.org/10.1016/j.scitotenv.2018.08.347. |
Random subset feature selection for ecological niche models of wildfire activity in western North America | J. L. Tracy, A. Trabucco, A. M. Lawing, J. T. Giermakowski, M. Tchakerian, G. M. Drus, R. N. Coulson | 2018 | Tracy, J.L., Trabucco, A., Lawing, A.M., Giermakowski, J.T., Tchakerian, M., Drus, G.M., and Coulson, R.N., 2018, Random subset feature selection for ecological niche models of wildfire activity in western North America: Ecological Modelling, v. 383, p. 52–68, at https://doi.org/10.1016/j.ecolmodel.2018.05.019. |
Toward consistent change detection across irregular remote sensing time series observations | H. J. Tollerud, Z. Zhu, K. Smith, D. F. Wellington, R. A. Hussain, D. Viola | 2023 | Tollerud, H.J., Zhu, Z., Smith, K., Wellington, D.F., Hussain, R.A., and Viola, D., 2023, Toward consistent change detection across irregular remote sensing time series observations: Remote Sensing of Environment, v. 285, article 113372, at https://doi.org/10.1016/j.rse.2022.113372. |
Managing for multiple species—Greater sage-grouse and sagebrush songbirds | J. M. Timmer, C. L. Aldridge, M. E. Fernandez-Gimenez | 2019 | Timmer, J.M., Aldridge, C.L., and Fernandez-Gimenez, M.E., 2019, Managing for multiple species—Greater sage-grouse and sagebrush songbirds: The Journal of Wildlife Management, v. 83, no. 5, p. 1043–1056, at https://doi.org/10.1002/jwmg.21663. |
Controls on debris-flow initiation on burned and unburned hillslopes during an exceptional rainstorm in southern New Mexico, USA | A. C. Tillery, F. K. Rengers | 2020 | Tillery, A.C., and Rengers, F.K., 2020, Controls on debris-flow initiation on burned and unburned hillslopes during an exceptional rainstorm in southern New Mexico, USA: Earth Surface Processes and Landforms, v. 45, no. 4, p. 1051–1066, at https://doi.org/10.1002/esp.4761. |
Automatic detection of forest fire disturbance based on dynamic modelling from MODIS time-series observations | L. Tian, J. D. Wang, H. M. Zhou, J. Wang | 2018 | Tian, L., Wang, J.D., Zhou, H.M., and Wang, J., 2018, Automatic detection of forest fire disturbance based on dynamic modelling from MODIS time-series observations: International Journal of Remote Sensing, v. 39, no. 12, p. 3801–3815, at https://doi.org/10.1080/01431161.2018.1437294. |
Integrated wildfire risk assessment—Framework development and application on the Lewis and Clark National Forest in Montana, USA | M. P. Thompson, J. Scott, D. Helmbrecht, D. E. Calkin | 2013 | Thompson, M.P., Scott, J., Helmbrecht, D., and Calkin, D.E., 2013, Integrated wildfire risk assessment—Framework development and application on the Lewis and Clark National Forest in Montana, USA: Integrated Environmental Assessment and Management, v. 9, no. 2, p. 329–342, at https://doi.org/10.1002/ieam.1365. |
Forest roads and operational wildfire response planning | M. P. Thompson, B. M. Gannon, M. D. Caggiano | 2021 | Thompson, M.P., Gannon, B.M., and Caggiano, M.D., 2021, Forest roads and operational wildfire response planning: Forests, v. 12, no. 2, article 110, at https://doi.org/10.3390/f12020110. |
Quantifying the influence of previously burned areas on suppression effectiveness and avoided exposure—A case study of the Las Conchas Fire | M. P. Thompson, P. Freeborn, J. D. Rieck, D. E. Calkin, J. W. Gilbertson-Day, M. A. Cochrane, M. S. Hand | 2016 | Thompson, M.P., Freeborn, P., Rieck, J.D., Calkin, D.E., Gilbertson-Day, J.W., Cochrane, M.A., and Hand, M.S., 2016, Quantifying the influence of previously burned areas on suppression effectiveness and avoided exposure—A case study of the Las Conchas Fire: International Journal of Wildland Fire, v. 25, no. 2, p. 167–181, at https://doi.org/10.1071/WF14216. |
Fisher use of postfire landscapes—Implications for habitat connectivity and restoration | C. Thompson, H. Smith, R. Creen, S. Wasser, K. Purcell | 2021 | Thompson, C., Smith, H., Creen, R., Wasser, S., and Purcell, K., 2021, Fisher use of postfire landscapes—Implications for habitat connectivity and restoration: Western North American Naturalist, v. 81, no. 2, p. 225–242, at https://doi.org/10.3398/064.081.0207. |
Validation of North American Forest Disturbance dynamics derived from Landsat time series stacks | N. E. Thomas, C. Huang, S. N. Goward, S. Powell, K. Rishmawi, K. Schleeweis, A. Hinds | 2011 | Thomas, N.E., Huang, C., Goward, S.N., Powell, S., Rishmawi, K., Schleeweis, K., and Hinds, A., 2011, Validation of North American Forest Disturbance dynamics derived from Landsat time series stacks: Remote Sensing of Environment, v. 115, no. 1, p. 19–32, at https://doi.org/10.1016/j.rse.2010.07.009. |
Biomass burning organic aerosol from prescribed burning and other activities in the United States | G. N. Theodoritsi, L. N. Posner, A. L. Robinson, G. Yarwood, B. Koo, R. Morris, M. Mavko, T. Moore, S. N. Pandis | 2020 | Theodoritsi, G.N., Posner, L.N., Robinson, A.L., Yarwood, G., Koo, B., Morris, R., Mavko, M., Moore, T., and Pandis, S.N., 2020, Biomass burning organic aerosol from prescribed burning and other activities in the United States: Atmospheric Environment, v. 241, article 117753, at https://doi.org/10.1016/j.atmosenv.2020.117753. |
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Modeling acute respiratory illness during the 2007 San Diego wildland fires using a coupled emissions-transport system and generalized additive modeling | B. Thelen, N. H. French, B. W. Koziol, M. Billmire, R. C. Owen, J. Johnson, M. Ginsberg, T. Loboda, S. Wu | 2013 | Thelen, B., French, N.H., Koziol, B.W., Billmire, M., Owen, R.C., Johnson, J., Ginsberg, M., Loboda, T., and Wu, S., 2013, Modeling acute respiratory illness during the 2007 San Diego wildland fires using a coupled emissions-transport system and generalized additive modeling: Environmental Health, v. 12, article 94, at https://doi.org/10.1186/1476-069X-12-94. |
Characterizing fire-on-fire interactions in three large wilderness areas | C. C. Teske, C. A. Seielstad, L. P. Queen | 2012 | Teske, C.C., Seielstad, C.A., and Queen, L.P., 2012, Characterizing fire-on-fire interactions in three large wilderness areas: Fire Ecology, v. 8, no. 2, p. 82–106, at https://doi.org/10.4996/fireecology.0802082. |
Population decline in California spotted owls near their southern range boundary | D. J. Tempel, H. A. Kramer, G. M. Jones, R. J. Gutiérrez, S. C. Sawyer, A. Koltunov, M. Slaton, R. Tanner, B. K. Hobart, M. Z. Peery | 2022 | Tempel, D.J., Kramer, H.A., Jones, G.M., Gutiérrez, R.J., Sawyer, S.C., Koltunov, A., Slaton, M., Tanner, R., Hobart, B.K., and Peery, M.Z., 2022, Population decline in California spotted owls near their southern range boundary: The Journal of Wildlife Management, v. 86, no. 2, article e22168, at https://doi.org/10.1002/jwmg.22168. |
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The economics of ecological restoration and hazardous fuel reduction treatments in the ponderosa pine forest ecosystem | M. H. Taylor, A. J. S. Meador, Y. S. Kim, K. Rollins, H. Will | 2015 | Taylor, M.H., Meador, A.J.S., Kim, Y.S., Rollins, K., and Will, H., 2015, The economics of ecological restoration and hazardous fuel reduction treatments in the ponderosa pine forest ecosystem: Forest Science, v. 61, no. 6, p. 988–1008, at https://doi.org/10.5849/forsci.14-030. |
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Forest management effects on vegetation regeneration after a high severity wildfire—A case study in the southern Cascade range | S. Sterner, C. Aslan, R. Best, T. Chaudhry | 2022 | Sterner, S., Aslan, C., Best, R., and Chaudhry, T., 2022, Forest management effects on vegetation regeneration after a high severity wildfire—A case study in the southern Cascade range: Forest Ecology and Management, v. 520, article 120394, at https://doi.org/10.1016/j.foreco.2022.120394. |
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Fire intensity impacts on post-fire temperate coniferous forest net primary productivity | A. M. Sparks, C. A. Kolden, A. M. S. Smith, L. Boschetti, D. M. Johnson, M. A. Cochrane | 2018 | Sparks, A.M., Kolden, C.A., Smith, A.M.S., Boschetti, L., Johnson, D.M., and Cochrane, M.A., 2018, Fire intensity impacts on post-fire temperate coniferous forest net primary productivity: Biogeosciences, v. 15, no. 4, p. 1173–1183, at https://doi.org/10.5194/bg-15-1173-2018. |
An accuracy assessment of the MTBS burned area product for shrub-steppe fires in the northern Great Basin, United States | A. M. Sparks, L. Boschetti, A. M. S. Smith, W. T. Tinkham, K. O. Lannom, B. A. Newingham | 2015 | Sparks, A.M., Boschetti, L., Smith, A.M.S., Tinkham, W.T., Lannom, K.O., and Newingham, B.A., 2015, An accuracy assessment of the MTBS burned area product for shrub-steppe fires in the northern Great Basin, United States: International Journal of Wildland Fire, v. 24, no. 1, p. 70–78, at https://doi.org/10.1071/WF14131. |
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Application of empirical land-cover changes to construct climate change scenarios in federally managed lands | C. E. Soulard, M. Rigge | 2020 | Soulard, C.E., and Rigge, M., 2020, Application of empirical land-cover changes to construct climate change scenarios in federally managed lands: Remote Sensing, v. 12, no. 15, article 2360, at https://doi.org/10.3390/rs12152360. |
Continuous 1985–2012 Landsat monitoring to assess fire effects on meadows in Yosemite National Park, California | C. E. Soulard, C. M. Albano, M. L. Villarreal, J. J. Walker | 2016 | Soulard, C.E., Albano, C.M., Villarreal, M.L., and Walker, J.J., 2016, Continuous 1985–2012 Landsat monitoring to assess fire effects on meadows in Yosemite National Park, California: Remote Sensing, v. 8, no. 5, article 371, at https://doi.org/10.3390/rs8050371. |
Harmonization of forest disturbance datasets of the conterminous USA from 1986 to 2011 | C. E. Soulard, W. Acevedo, W. B. Cohen, Z. Yang, S. V. Stehman, J. L. Taylor | 2017 | Soulard, C.E., Acevedo, W., Cohen, W.B., Yang, Z., Stehman, S.V., and Taylor, J.L., 2017, Harmonization of forest disturbance datasets of the conterminous USA from 1986 to 2011: Environmental Monitoring and Assessment, v. 189, no. 4, article 170, at https://doi.org/10.1007/s10661-017-5879-5. |
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The drivers and predictability of wildfire re-burns in the western United States (US) | K. C. Solander, C. J. Talsma, V. V. Vesselinov | 2023 | Solander, K.C., Talsma, C.J., and Vesselinov, V.V., 2023, The drivers and predictability of wildfire re-burns in the western United States (US): Environmental Research—Climate, v. 2, no. 1, article 015001, at https://doi.org/10.1088/2752-5295/acb079. |
The relationship between invader abundance and impact | S. R. Sofaer, C. S. Jarnevich, I. S. Pearse | 2018 | Sofaer, S.R., Jarnevich, C.S., and Pearse, I.S., 2018, The relationship between invader abundance and impact: Ecosphere, v. 9, no. 9, article e02415, at https://doi.org/10.1002/ecs2.2415. |
Assessing giant sequoia mortality and regeneration following high?severity wildfire | D. N. Soderberg, A. J. Das, N. L. Stephenson, M. D. Meyer, C. A. Brigham, J. Flickinger | 2024 | Soderberg, D.N., Das, A.J., Stephenson, N.L., Meyer, M.D., Brigham, C.A., and Flickinger, J., 2024, Assessing giant sequoia mortality and regeneration following high?severity wildfire: Ecosphere, v. 15, no. 3, article e4789, at https://doi.org/10.1002/ecs2.4789. |
Sagebrush treatments influence annual population change for greater sage-grouse | K. T. Smith, J. L. Beck | 2017 | Smith, K.T., and Beck, J.L., 2017, Sagebrush treatments influence annual population change for greater sage-grouse: Restoration Ecology, v. 26, no. 3, p. 497–505, at https://doi.org/10.1111/rec.12589. |
Fire needs annual grasses more than annual grasses need fire | J. T. Smith, B. W. Allred, C. S. Boyd, K. W. Davies, A. R. Kleinhesselink, S. L. Morford, D. E. Naugle | 2023 | Smith, J.T., Allred, B.W., Boyd, C.S., Davies, K.W., Kleinhesselink, A.R., Morford, S.L., and Naugle, D.E., 2023, Fire needs annual grasses more than annual grasses need fire: Biological Conservation, v. 286, article 110299, at https://doi.org/10.1016/j.biocon.2023.110299. |
Where there's smoke, there's fuel—Dynamic vegetation data improve predictions of wildfire hazard in the Great Basin | J. T. Smith, B. W. Allred, C. S. Boyd, K. W. Davies, M. O. Jones, A. R. Kleinhesselink, J. D. Maestas, D. E. Naugle | 2023 | Smith, J.T., Allred, B.W., Boyd, C.S., Davies, K.W., Jones, M.O., Kleinhesselink, A.R., Maestas, J.D., and Naugle, D.E., 2023, Where there's smoke, there's fuel—Dynamic vegetation data improve predictions of wildfire hazard in the Great Basin: Rangeland Ecology & Management, v. 89, p. 20–32, at https://doi.org/10.1016/j.rama.2022.07.005. |
Evaluation of low-resolution remotely sensed datasets for burned area assessment within the wildland-urban interface | H. Smith, K. M. de Beurs, T. M. Neeson | 2022 | Smith, H., de Beurs, K.M., and Neeson, T.M., 2022, Evaluation of low-resolution remotely sensed datasets for burned area assessment within the wildland-urban interface: Remote Sensing Applications—Society and Environment, v. 26, article 100752, at https://doi.org/10.1016/j.rsase.2022.100752. |
Quantifying drivers of coastal forest carbon decline highlights opportunities for targeted human interventions | L. S. Smart, J. Vukomanovic, P. J. Taillie, K. K. Singh, J. W. Smith | 2021 | Smart, L.S., Vukomanovic, J., Taillie, P.J., Singh, K.K., and Smith, J.W., 2021, Quantifying drivers of coastal forest carbon decline highlights opportunities for targeted human interventions: Land, v. 10, no. 7, article 752, at https://doi.org/10.3390/land10070752. |
Aboveground carbon loss associated with the spread of ghost forests as sea levels rise | L. S. Smart, P. J. Taillie, B. Poulter, J. Vukomanovic, K. K. Singh, J. J. Swenson, H. Mitasova, J. W. Smith, R. K. Meentemeyer | 2020 | Smart, L.S., Taillie, P.J., Poulter, B., Vukomanovic, J., Singh, K.K., Swenson, J.J., Mitasova, H., Smith, J.W., and Meentemeyer, R.K., 2020, Aboveground carbon loss associated with the spread of ghost forests as sea levels rise: Environmental Research Letters, v. 15, no. 10, article 104028, at https://doi.org/10.1088/1748-9326/aba136. |
Methods used to parameterize the spatially-explicit components of a state-and-transition simulation model | R. R. Sleeter, W. Acevedo, C. E. Soulard, B. M. Sleeter | 2015 | Sleeter, R.R., Acevedo, W., Soulard, C.E., and Sleeter, B.M., 2015, Methods used to parameterize the spatially-explicit components of a state-and-transition simulation model: AIMS Environmental Science, v. 2, no. 3, p. 668–693, at https://doi.org/10.3934/environsci.2015.3.668. |
A carbon balance model for the great dismal swamp ecosystem | R. Sleeter, B. M. Sleeter, B. Williams, D. Hogan, T. Hawbaker, Z. Zhu | 2017 | Sleeter, R., Sleeter, B.M., Williams, B., Hogan, D., Hawbaker, T., and Zhu, Z., 2017, A carbon balance model for the great dismal swamp ecosystem: Carbon Balance and Management, v. 12, no. 1, article 2, at https://doi.org/10.1186/s13021-017-0070-4. |
Future scenarios of land change based on empirical data and demographic trends | B. M. Sleeter, T. S. Wilson, E. Sharygin, J. T. Sherba | 2017 | Sleeter, B.M., Wilson, T.S., Sharygin, E., and Sherba, J.T., 2017, Future scenarios of land change based on empirical data and demographic trends: Earth's Future, v. 5, no. 11, p. 1068–1083, at https://doi.org/10.1002/2017ef000560. |
Scenarios of land use and land cover change in the conterminous United States—Utilizing the special report on emission scenarios at ecoregional scales | B. M. Sleeter, T. L. Sohl, M. A. Bouchard, R. R. Reker, C. E. Soulard, W. Acevedo, G. E. Griffith, R. R. Sleeter, R. F. Auch, K. L. Sayler, S. Prisley, Z. Zhu | 2012 | Sleeter, B.M., Sohl, T.L., Bouchard, M.A., Reker, R.R., Soulard, C.E., Acevedo, W., Griffith, G.E., Sleeter, R.R., Auch, R.F., et al., 2012, Scenarios of land use and land cover change in the conterminous United States—Utilizing the special report on emission scenarios at ecoregional scales: Global Environmental Change, v. 22, no. 4, p. 896–914, at https://doi.org/10.1016/j.gloenvcha.2012.03.008. |
Effects of contemporary land-use and land-cover change on the carbon balance of terrestrial ecosystems in the United States | B. M. Sleeter, J. Liu, C. Daniel, B. Rayfield, J. Sherba, T. J. Hawbaker, Z. Zhu, P. C. Selmants, T. R. Loveland | 2018 | Sleeter, B.M., Liu, J., Daniel, C., Rayfield, B., Sherba, J., Hawbaker, T.J., Zhu, Z., Selmants, P.C., and Loveland, T.R., 2018, Effects of contemporary land-use and land-cover change on the carbon balance of terrestrial ecosystems in the United States: Environmental Research Letters, v. 13, no. 4, article 045006, at https://doi.org/10.1088/1748-9326/aab540. |
Operational assessment tool for forest carbon dynamics for the United States—A new spatially explicit approach linking the LUCAS and CBM-CFS3 models | B. M. Sleeter, L. Frid, B. Rayfield, C. Daniel, Z. Zhu, D. C. Marvin | 2022 | Sleeter, B.M., Frid, L., Rayfield, B., Daniel, C., Zhu, Z., and Marvin, D.C., 2022, Operational assessment tool for forest carbon dynamics for the United States—A new spatially explicit approach linking the LUCAS and CBM-CFS3 models: Carbon Balance and Management, v. 17, no. 1, article 1, at https://doi.org/10.1186/s13021-022-00201-1. |
Effects of megafire on woody species in the mixed-grass prairie | M. W. Sirch, D. S. Sullins, N. J. Parker, D. A. Haukos, J. D. Kraft, C. A. Hagen, K. A. Fricke | 2022 | Sirch, M.W., Sullins, D.S., Parker, N.J., Haukos, D.A., Kraft, J.D., Hagen, C.A., and Fricke, K.A., 2022, Effects of megafire on woody species in the mixed-grass prairie: Prairie Naturalist, v. 52, p. 11–23, at https://www.eaglehill.us/prna-pdfs-regular/prna-54/prna-008-Sirch.pdf. |
Management strategy influences landscape patterns of high-severity burn patches in the southwestern United States | M. P. Singleton, A. E. Thode, A. J. S. Meador, J. M. Iniguez, J. T. Stevens | 2021 | Singleton, M.P., Thode, A.E., Meador, A.J.S., Iniguez, J.M., and Stevens, J.T., 2021, Management strategy influences landscape patterns of high-severity burn patches in the southwestern United States: Landscape Ecology, v. 36, no. 12, p. 3429–3449, at https://doi.org/10.1007/s10980-021-01318-3. |
Moisture and vegetation cover limit ponderosa pine regeneration in high-severity burn patches in the southwestern US | M. P. Singleton, A. E. Thode, A. J. Sánchez Meador, J. M. Iniguez | 2021 | Singleton, M.P., Thode, A.E., Sánchez Meador, A.J., and Iniguez, J.M., 2021, Moisture and vegetation cover limit ponderosa pine regeneration in high-severity burn patches in the southwestern US: Fire Ecology, v. 17, no. 1, article 14, at https://doi.org/10.1186/s42408-021-00095-3. |
Increasing trends in high-severity fire in the southwestern USA from 1984 to 2015 | M. P. Singleton, A. E. Thode, A. J. Sánchez Meador, J. M. Iniguez | 2019 | Singleton, M.P., Thode, A.E., Sánchez Meador, A.J., and Iniguez, J.M., 2019, Increasing trends in high-severity fire in the southwestern USA from 1984 to 2015: Forest Ecology and Management, v. 433, p. 709–719, at https://doi.org/10.1016/j.foreco.2018.11.039. |
Analysis of how the spatial and temporal patterns of fire and their bioclimatic and anthropogenic drivers vary across the Amazon rainforest in El Niño and non-El Niño years | M. Singh, X. Zhu | 2021 | Singh, M., and Zhu, X., 2021, Analysis of how the spatial and temporal patterns of fire and their bioclimatic and anthropogenic drivers vary across the Amazon rainforest in El Niño and non-El Niño years: PeerJ, v. 9, article e12029, at https://doi.org/10.7717/peerj.12029. |
Using aggregated field collection data and the novel R package FUNGARIUM to investigate fungal fire association | H. J. Simpson, J. S. Schilling | 2021 | Simpson, H.J., and Schilling, J.S., 2021, Using aggregated field collection data and the novel R package FUNGARIUM to investigate fungal fire association: Mycologia, v. 113, no. 4, p. 842–855, at https://doi.org/10.1080/00275514.2021.1884816. |
Statistical considerations of nonrandom treatment applications reveal region-wide benefits of widespread post-fire restoration action | A. B. Simler-Williamson, M. J. Germino | 2022 | Simler-Williamson, A.B., and Germino, M.J., 2022, Statistical considerations of nonrandom treatment applications reveal region-wide benefits of widespread post-fire restoration action: Nature Communications, v. 13, no. 1, article 3472, at https://doi.org/10.1038/s41467-022-31102-z. |
Nesting success of wood-cavity-nesting bees declines with increasing time since wildfire | M. P. Simanonok, L. A. Burkle | 2019 | Simanonok, M.P., and Burkle, L.A., 2019, Nesting success of wood-cavity-nesting bees declines with increasing time since wildfire: Ecology and Evolution, v. 9, no. 22, p. 12436–12445, at https://doi.org/10.1002/ece3.5657. |
High-severity wildfire limits available floral pollen quality and bumble bee nutrition compared to mixed-severity burns | M. P. Simanonok, L. A. Burkle | 2019 | Simanonok, M.P., and Burkle, L.A., 2019, High-severity wildfire limits available floral pollen quality and bumble bee nutrition compared to mixed-severity burns: Oecologia, v. 192, no. 2, p. 489–499, at https://doi.org/10.1007/s00442-019-04577-9. |
Modeling wildland fire burn severity in California using a spatial Super Learner approach | N. Simafranca, B. Willoughby, E. O’Neil, S. Farr, B. J. Reich, N. Giertych, M. C. Johnson, M. A. Pascolini-Campbell | in press | Simafranca, N., Willoughby, B., O’Neil, E., Farr, S., Reich, B.J., Giertych, N., Johnson, M.C., and Pascolini-Campbell, M.A., in press, Modeling wildland fire burn severity in California using a spatial Super Learner approach: Environmental and Ecological Statistics, at https://doi.org/10.1007/s10651-024-00601-1. |
Using Sentinel-2 images and spectral indices for severity analysis in burned areas of anthropic origin—A study in the southeast of the Amazon | A. B. N. da Silva, N. E. S. Beltrão, L. B. Santos | 2023 | da Silva, A.B.N., Beltrão, N.E.S., and Santos, L.B., 2023, Using Sentinel-2 images and spectral indices for severity analysis in burned areas of anthropic origin—A study in the southeast of the Amazon: Revista Brasileira de Geografia Fisica, v. 16, no. 1, p. 489–504, at https://doi.org/10.26848/rbgf.v16.1.p489-504. |
Quantifying drivers of change in social-ecological systems—Land management impacts wildfire probability in forests of the western US | K. J. Siegel, L. Larsen, C. Stephens, W. Stewart, V. Butsic | 2022 | Siegel, K.J., Larsen, L., Stephens, C., Stewart, W., and Butsic, V., 2022, Quantifying drivers of change in social-ecological systems—Land management impacts wildfire probability in forests of the western US: Regional Environmental Change, v. 22, no. 3, article 98, at https://doi.org/10.1007/s10113-022-01950-y. |
A coupled modelling approach to assess the effect of fuel treatments on post-wildfire runoff and erosion | G. Sidman, D. P. Guertin, D. C. Goodrich, D. Thoma, D. Falk, I. S. Burns | 2016 | Sidman, G., Guertin, D.P., Goodrich, D.C., Thoma, D., Falk, D., and Burns, I.S., 2016, A coupled modelling approach to assess the effect of fuel treatments on post-wildfire runoff and erosion: International Journal of Wildland Fire, v. 25, no. 3, p. 351–362, at https://doi.org/10.1071/WF14058. |
An approach for the long-term 30-m land surface snow-free albedo retrieval from historic Landsat surface reflectance and MODIS-based a priori anisotropy knowledge | Y. Shuai, J. G. Masek, F. Gao, C. B. Schaaf, T. He | 2014 | Shuai, Y., Masek, J.G., Gao, F., Schaaf, C.B., and He, T., 2014, An approach for the long-term 30-m land surface snow-free albedo retrieval from historic Landsat surface reflectance and MODIS-based a priori anisotropy knowledge: Remote Sensing of Environment, v. 152, p. 467–479, at https://doi.org/10.1016/j.rse.2014.07.009. |
Wildfire controls on land surface properties in mixed conifer and ponderosa pine forests of Sierra Nevada and Klamath mountains, western US | S. Shrestha, C. A. Williams, B. M. Rogers, J. Rogan, D. Kulakowski | 2022 | Shrestha, S., Williams, C.A., Rogers, B.M., Rogan, J., and Kulakowski, D., 2022, Wildfire controls on land surface properties in mixed conifer and ponderosa pine forests of Sierra Nevada and Klamath mountains, western US: Agricultural and Forest Meteorology, v. 320, article 108939, at https://doi.org/10.1016/j.agrformet.2022.108939. |
Sources and implications of bias and uncertainty in a century of US wildfire activity data | K. C. Short | 2015 | Short, K.C., 2015, Sources and implications of bias and uncertainty in a century of US wildfire activity data: International Journal of Wildland Fire, v. 24, no. 7, p. 883–891, at https://doi.org/10.1071/WF14190. |
A spatial database of wildfires in the United States, 1992–2011 | K. C. Short | 2014 | Short, K.C., 2014, A spatial database of wildfires in the United States, 1992–2011: Earth System Science Data, v. 6, no. 1, p. 1–27, at https://doi.org/10.5194/essd-6-1-2014. |
Ancient trees and modern wildfires—Declining resilience to wildfire in the highly fire-adapted giant sequoia | K. L. Shive, A. Wuenschel, L. J. Hardlund, S. Morris, M. D. Meyer, S. M. Hood | 2022 | Shive, K.L., Wuenschel, A., Hardlund, L.J., Morris, S., Meyer, M.D., and Hood, S.M., 2022, Ancient trees and modern wildfires—Declining resilience to wildfire in the highly fire-adapted giant sequoia: Forest Ecology and Management, v. 511, article 120110, at https://doi.org/10.1016/j.foreco.2022.120110. |
Future direction of fuels management in sagebrush rangelands | D. J. Shinneman, E. K. Strand, M. Pellant, J. T. Abatzoglou, M. W. Brunson, N. F. Glenn, J. A. Heinrichs, M. Sadegh, N. M. Vaillant | 2023 | Shinneman, D.J., Strand, E.K., Pellant, M., Abatzoglou, J.T., Brunson, M.W., Glenn, N.F., Heinrichs, J.A., Sadegh, M., and Vaillant, N.M., 2023, Future direction of fuels management in sagebrush rangelands: Rangeland Ecology & Management, v. 89, p. 113–126, at https://doi.org/10.1016/j.rama.2023.01.011. |
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Disentangling the effects of multiple fires on spatially interspersed sagebrush (Artemisia spp.) communities | D. J. Shinneman, S. K. McIlroy, M. A. de Graaff, A. Fidelis | 2020 | Shinneman, D.J., McIlroy, S.K., de Graaff, M.A., and Fidelis, A., 2020, Disentangling the effects of multiple fires on spatially interspersed sagebrush (Artemisia spp.) communities: Journal of Vegetation Science, v. 32, no. 1, article e12937, at https://doi.org/10.1111/jvs.12937. |
Climate and disturbance influence self-sustaining stand dynamics of aspen (Populus tremuloides) near its range margin | D. J. Shinneman, S. K. McIlroy | 2019 | Shinneman, D.J., and McIlroy, S.K., 2019, Climate and disturbance influence self-sustaining stand dynamics of aspen (Populus tremuloides) near its range margin: Ecological Applications, v. 29, no. 6, article e01948, at https://doi.org/10.1002/eap.1948. |
Trends analysis of rangeland condition monitoring assessment and projection (RCMAP) fractional component time series (1985–2020) | H. Shi, M. Rigge, K. Postma, B. Bunde | 2022 | Shi, H., Rigge, M., Postma, K., and Bunde, B., 2022, Trends analysis of rangeland condition monitoring assessment and projection (RCMAP) fractional component time series (1985–2020): GIScience & Remote Sensing, v. 59, no. 1, p. 1243–1265, at https://doi.org/10.1080/15481603.2022.2104786. |
Historical cover trends in a sagebrush steppe ecosystem from 1985 to 2013—Links with climate, disturbance, and management | H. Shi, M. Rigge, C. G. Homer, G. Xian, D. K. Meyer, B. Bunde | 2017 | Shi, H., Rigge, M., Homer, C.G., Xian, G., Meyer, D.K., and Bunde, B., 2017, Historical cover trends in a sagebrush steppe ecosystem from 1985 to 2013—Links with climate, disturbance, and management: Ecosystems, v. 21, no. 5, p. 913–929, at https://doi.org/10.1007/s10021-017-0191-3. |
Analyzing vegetation change in a sagebrush ecosystem using long?term field observations and Landsat imagery in Wyoming | H. Shi, C. G. Homer, M. B. Rigge, K. Postma, G. Xian | 2020 | Shi, H., Homer, C.G., Rigge, M.B., Postma, K., and Xian, G., 2020, Analyzing vegetation change in a sagebrush ecosystem using long?term field observations and Landsat imagery in Wyoming: Ecosphere, v. 11, no. 12, article e03311, at https://doi.org/10.1002/ecs2.3311. |
Spatial variation in postfire cheatgrass—Dinosaur National Monument, USA | K. R. Sherrill, W. H. Romme | 2012 | Sherrill, K.R., and Romme, W.H., 2012, Spatial variation in postfire cheatgrass—Dinosaur National Monument, USA: Fire Ecology, v. 8, no. 2, p. 38–56, at https://doi.org/10.4996/fireecology.0802038. |
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Spatial variability in seasonal snowpack trends across the Rio Grande headwaters (1984–2017) | G. A. Sexstone, C. A. Penn, G. E. Liston, K. E. Gleason, C. D. Moeser, D. W. Clow | 2020 | Sexstone, G.A., Penn, C.A., Liston, G.E., Gleason, K.E., Moeser, C.D., and Clow, D.W., 2020, Spatial variability in seasonal snowpack trends across the Rio Grande headwaters (1984–2017): Journal of Hydrometeorology, v. 21, no. 11, p. 2713–2733, at https://doi.org/10.1175/Jhm-D-20-0077.1. |
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Estimating heterogeneous wildfire effects using synthetic controls and satellite remote sensing | F. Serra-Burriel, P. Delicado, A. T. Prata, F. M. Cucchietti | 2021 | Serra-Burriel, F., Delicado, P., Prata, A.T., and Cucchietti, F.M., 2021, Estimating heterogeneous wildfire effects using synthetic controls and satellite remote sensing: Remote Sensing of Environment, v. 265, article 112649, at https://doi.org/10.1016/j.rse.2021.112649. |
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Probabilistic assessment of wildfire hazard and municipal watershed exposure | J. Scott, D. Helmbrecht, M. P. Thompson, D. E. Calkin, K. Marcille | 2012 | Scott, J., Helmbrecht, D., Thompson, M.P., Calkin, D.E., and Marcille, K., 2012, Probabilistic assessment of wildfire hazard and municipal watershed exposure: Natural Hazards, v. 64, no. 1, p. 707–728, at https://doi.org/10.1007/s11069-012-0265-7. |
Smoke from regional wildfires alters lake ecology | F. Scordo, S. Chandra, E. Suenaga, S. J. Kelson, J. Culpepper, L. Scaff, F. Tromboni, T. J. Caldwell, C. Seitz, J. E. Fiorenza, C. E. Williamson, S. Sadro, K. C. Rose, S. R. Poulson | 2021 | Scordo, F., Chandra, S., Suenaga, E., Kelson, S.J., Culpepper, J., Scaff, L., Tromboni, F., Caldwell, T.J., Seitz, C., et al., 2021, Smoke from regional wildfires alters lake ecology: Scientific Reports, v. 11, no. 1, article 10922, at https://doi.org/10.1038/s41598-021-89926-6. |
Assessing relative differences in smoke exposure from prescribed, managed, and full suppression wildland fire | D. Schweizer, H. K. Preisler, R. Cisneros | 2018 | Schweizer, D., Preisler, H.K., and Cisneros, R., 2018, Assessing relative differences in smoke exposure from prescribed, managed, and full suppression wildland fire: Air Quality, Atmosphere & Health, v. 12, no. 1, p. 87–95, at https://doi.org/10.1007/s11869-018-0633-x. |
Quantifying drought-induced tree mortality in the open canopy woodlands of central Texas | A. M. Schwantes, J. J. Swenson, R. B. Jackson | 2016 | Schwantes, A.M., Swenson, J.J., and Jackson, R.B., 2016, Quantifying drought-induced tree mortality in the open canopy woodlands of central Texas: Remote Sensing of Environment, v. 181, p. 54–64, at https://doi.org/10.1016/j.rse.2016.03.027. |
Measuring canopy loss and climatic thresholds from an extreme drought along a fivefold precipitation gradient across Texas | A. M. Schwantes, J. J. Swenson, M. Gonzalez-Roglich, D. M. Johnson, J. C. Domec, R. B. Jackson | 2017 | Schwantes, A.M., Swenson, J.J., Gonzalez-Roglich, M., Johnson, D.M., Domec, J.C., and Jackson, R.B., 2017, Measuring canopy loss and climatic thresholds from an extreme drought along a fivefold precipitation gradient across Texas: Global Change Biology, v. 23, no. 12, p. 5120–5135, at https://doi.org/10.1111/gcb.13775. |
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Prediction of water distribution system contamination based on wildfire burn severity in wildland urban interface communities | S. S. Schulze, E. C. Fischer | 2020 | Schulze, S.S., and Fischer, E.C., 2020, Prediction of water distribution system contamination based on wildfire burn severity in wildland urban interface communities: ACS ES&T Water, v. 1, no. 2, p. 291–299, at https://doi.org/10.1021/acsestwater.0c00073. |
Testing a Landsat-based approach for mapping disturbance causality in U.S. forests | T. A. Schroeder, K. G. Schleeweis, G. G. Moisen, C. Toney, W. B. Cohen, E. A. Freeman, Z. Yang, C. Huang | 2017 | Schroeder, T.A., Schleeweis, K.G., Moisen, G.G., Toney, C., Cohen, W.B., Freeman, E.A., Yang, Z., and Huang, C., 2017, Testing a Landsat-based approach for mapping disturbance causality in U.S. forests: Remote Sensing of Environment, v. 195, p. 230–243, at https://doi.org/10.1016/j.rse.2017.03.033. |
Improving estimates of forest disturbance by combining observations from Landsat time series with U.S. Forest Service Forest Inventory and Analysis data | T. A. Schroeder, S. P. Healey, G. G. Moisen, T. S. Frescino, W. B. Cohen, C. Huang, R. E. Kennedy, Z. Yang | 2014 | Schroeder, T.A., Healey, S.P., Moisen, G.G., Frescino, T.S., Cohen, W.B., Huang, C., Kennedy, R.E., and Yang, Z., 2014, Improving estimates of forest disturbance by combining observations from Landsat time series with U.S. Forest Service Forest Inventory and Analysis data: Remote Sensing of Environment, v. 154, no. 1, p. 61–73, at https://doi.org/10.1016/j.rse.2014.08.005. |
Soil seed bank composition and spatial distribution in a cheatgrass (Bromus tectorum L.)–dominated rangeland in Colorado, USA | R. W. R. Schroeder, J. L. Jonas, M. N. Grant-Hoffman, M. W. Paschke | 2023 | Schroeder, R.W.R., Jonas, J.L., Grant-Hoffman, M.N., and Paschke, M.W., 2023, Soil seed bank composition and spatial distribution in a cheatgrass (Bromus tectorum L.)–dominated rangeland in Colorado, USA: Western North American Naturalist, v. 83, no. 2, p. 191–206, at https://doi.org/10.3398/064.083.0205. |
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Grassland fragmentation and its influence on woody plant cover in the southern Great Plains, USA | R. Scholtz, J. A. Polo, E. P. Tanner, S. D. Fuhlendorf | 2018 | Scholtz, R., Polo, J.A., Tanner, E.P., and Fuhlendorf, S.D., 2018, Grassland fragmentation and its influence on woody plant cover in the southern Great Plains, USA: Landscape Ecology, v. 33, no. 10, p. 1785–1797, at https://doi.org/10.1007/s10980-018-0702-4. |
Climate-fire interactions constrain potential woody plant cover and stature in North American Great Plains grasslands | R. Scholtz, S. D. Fuhlendorf, S. R. Archer | 2018 | Scholtz, R., Fuhlendorf, S.D., and Archer, S.R., 2018, Climate-fire interactions constrain potential woody plant cover and stature in North American Great Plains grasslands: Global Ecology and Biogeography, v. 27, no. 8, p. 936–945, at https://doi.org/10.1111/geb.12752. |
Development of a source-specific biomass burning emissions inventory for Washington, Oregon, and California | C. L. Schollaert, M. E. Marlier, T. M. Busch Isaksen | 2024 | Schollaert, C.L., Marlier, M.E., and Busch Isaksen, T.M., 2024, Development of a source-specific biomass burning emissions inventory for Washington, Oregon, and California: Atmospheric Environment, v. 319, article 120283, at https://doi.org/10.1016/j.atmosenv.2023.120283. |
Adapt to more wildfire in western North American forests as climate changes | T. Schoennagel, J. K. Balch, H. Brenkert-Smith, P. E. Dennison, B. J. Harvey, M. A. Krawchuk, N. Mietkiewicz, P. Morgan, M. A. Moritz, R. Rasker, M. G. Turner, C. Whitlock | 2017 | Schoennagel, T., Balch, J.K., Brenkert-Smith, H., Dennison, P.E., Harvey, B.J., Krawchuk, M.A., Mietkiewicz, N., Morgan, P., Moritz, M.A., et al., 2017, Adapt to more wildfire in western North American forests as climate changes: Proceedings of the National Academy of Sciences of the United States of America, v. 114, no. 18, p. 4582–4590, at https://doi.org/10.1073/pnas.1617464114. |
A quantitative wildfire risk assessment using a modular approach of geostatistical clustering and regionally distinct valuations of assets—A case study in Oregon | A. Schmidt, D. Leavell, J. Punches, M. A. Rocha Ibarra, J. S. Kagan, M. Creutzburg, M. McCune, J. Salwasser, C. Walter, C. Berger | 2022 | Schmidt, A., Leavell, D., Punches, J., Rocha Ibarra, M.A., Kagan, J.S., Creutzburg, M., McCune, M., Salwasser, J., Walter, C., and Berger, C., 2022, A quantitative wildfire risk assessment using a modular approach of geostatistical clustering and regionally distinct valuations of assets—A case study in Oregon: PLoS ONE, v. 17, no. 3, article e0264826, at https://doi.org/10.1371/journal.pone.0264826. |
Bayesian optimization of the community land model simulated biosphere–atmosphere exchange using CO2 observations from a dense tower network and aircraft campaigns over Oregon | A. Schmidt, B. E. Law, M. Göckede, C. Hanson, Z. Yang, S. Conley | 2016 | Schmidt, A., Law, B.E., Göckede, M., Hanson, C., Yang, Z., and Conley, S., 2016, Bayesian optimization of the community land model simulated biosphere–atmosphere exchange using CO2 observations from a dense tower network and aircraft campaigns over Oregon: Earth Interactions, v. 20, no. 22, article 22, at https://doi.org/10.1175/ei-d-16-0011.1. |
Application of deep convolutional networks for improved risk assessments of post-wildfire drinking water contamination | A. Schmidt, L. M. Ellsworth, J. H. Tilt, M. Gough | 2023 | Schmidt, A., Ellsworth, L.M., Tilt, J.H., and Gough, M., 2023, Application of deep convolutional networks for improved risk assessments of post-wildfire drinking water contamination: Machine Learning with Applications, v. 11, article 100454, at https://doi.org/10.1016/j.mlwa.2023.100454. |
Predicting conditional maximum contaminant level exceedance probabilities for drinking water after wildfires with Bayesian regularized network ensembles | A. Schmidt, L. M. Ellsworth, J. H. Tilt, M. Gough | 2022 | Schmidt, A., Ellsworth, L.M., Tilt, J.H., and Gough, M., 2022, Predicting conditional maximum contaminant level exceedance probabilities for drinking water after wildfires with Bayesian regularized network ensembles: Machine Learning with Applications, v. 7, article 100227, at https://doi.org/10.1016/j.mlwa.2021.100227. |
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Improved burn severity estimation by using land surface phenology metrics and red edge information estimated from Landsat | D. Scheffler, D. Frantz | 2022 | Scheffler, D., and Frantz, D., 2022, Improved burn severity estimation by using land surface phenology metrics and red edge information estimated from Landsat: International Journal of Applied Earth Observation and Geoinformation, v. 115, article 103126, at https://doi.org/10.1016/j.jag.2022.103126. |
Subalpine tree seedlings—Assessing aging methodology and drivers of establishment | Z. H. Schapira, C. S. Stevens-Rumann, D. Shorrock | 2021 | Schapira, Z.H., Stevens-Rumann, C.S., and Shorrock, D., 2021, Subalpine tree seedlings—Assessing aging methodology and drivers of establishment: Forest Ecology and Management, v. 497, article 119516, at https://doi.org/10.1016/j.foreco.2021.119516. |
Beetlemania—Is the bark worse than the bite? Rocky Mountain subalpine forests recover differently after spruce beetle outbreaks and wildfires | Z. Schapira, C. Stevens-Rumann, D. Shorrock, C. Hoffman, A. Chambers | 2021 | Schapira, Z., Stevens-Rumann, C., Shorrock, D., Hoffman, C., and Chambers, A., 2021, Beetlemania—Is the bark worse than the bite? Rocky Mountain subalpine forests recover differently after spruce beetle outbreaks and wildfires: Forest Ecology and Management, v. 482, article 118879, at https://doi.org/10.1016/j.foreco.2020.118879. |
Characterization and evaluation of controls on post-fire streamflow response across western US watersheds | S. Saxe, T. S. Hogue, L. Hay | 2018 | Saxe, S., Hogue, T.S., and Hay, L., 2018, Characterization and evaluation of controls on post-fire streamflow response across western US watersheds: Hydrology and Earth System Sciences, v. 22, no. 2, p. 1221–1237, at https://doi.org/10.5194/hess-22-1221-2018. |
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Climate, wildfire, and erosion ensemble foretells more sediment in western USA watersheds | J. B. Sankey, J. Kreitler, T. J. Hawbaker, J. L. Mcvay, M. E. Miller, E. R. Mueller, N. M. Vaillant, S. E. Lowe, T. T. Sankey | 2017 | Sankey, J.B., Kreitler, J., Hawbaker, T.J., Mcvay, J.L., Miller, M.E., Mueller, E.R., Vaillant, N.M., Lowe, S.E., and Sankey, T.T., 2017, Climate, wildfire, and erosion ensemble foretells more sediment in western USA watersheds: Geophysical Research Letters, v. 44, no. 17, p. 8884–8892, at https://doi.org/10.1002/2017gl073979. |
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Physical and biogeochemical drivers of solute mobilization and flux through the critical zone after wildfire | R. A. Sánchez, T. Meixner, T. Roy, P. T. Ferré, M. Whitaker, J. Chorover | 2023 | Sánchez, R.A., Meixner, T., Roy, T., Ferré, P.T., Whitaker, M., and Chorover, J., 2023, Physical and biogeochemical drivers of solute mobilization and flux through the critical zone after wildfire: Frontiers in Water, v. 5, article 1148298, at https://doi.org/10.3389/frwa.2023.1148298. |
Where, when and how is the occurrence of large fires in La Pampa Province, Argentina—A remote sensing characterization | M. Sanchez, P. Baldassini, M. Á. Fischer, J. Zaffaroni, C. Di Bella | 2023 | Sanchez, M., Baldassini, P., Fischer, M.Á., Zaffaroni, J., and Di Bella, C., 2023, Where, when and how is the occurrence of large fires in La Pampa Province, Argentina—A remote sensing characterization: Ecologia Austral, v. 33, no. 1, p. 211–228, at https://doi.org/10.25260/EA.23.33.1.0.1972. |
Quantifying local fire regimes using the Landsat data-archive—A conceptual framework to derive detailed fire pattern metrics from pixel-level information | I. San-Miguel, D. W. Andison, N. C. Coops | 2018 | San-Miguel, I., Andison, D.W., and Coops, N.C., 2018, Quantifying local fire regimes using the Landsat data-archive—A conceptual framework to derive detailed fire pattern metrics from pixel-level information: International Journal of Digital Earth, v. 12, no. 5, p. 544–565, at https://doi.org/10.1080/17538947.2018.1464072. |
Wildfire trend analysis over the contiguous United States using remote sensing observations | J. Salguero, J. Li, A. Farahmand, J. T. Reager | 2020 | Salguero, J., Li, J., Farahmand, A., and Reager, J.T., 2020, Wildfire trend analysis over the contiguous United States using remote sensing observations: Remote Sensing, v. 12, no. 16, article 2565, at https://doi.org/10.3390/rs12162565. |
Fire history and vegetation data reveal ecological benefits of recent mixed-severity fires in the Cumberland Mountains, West Virginia, USA | T. Saladyga, K. A. Palmquist, C. M. Bacon | 2022 | Saladyga, T., Palmquist, K.A., and Bacon, C.M., 2022, Fire history and vegetation data reveal ecological benefits of recent mixed-severity fires in the Cumberland Mountains, West Virginia, USA: Fire Ecology, v. 18, no. 1, article 19, at https://doi.org/10.1186/s42408-022-00143-6. |
Low-severity wildfire shifts mixed conifer forests toward historical stand structure in Guadalupe Mountains National Park, Texas, USA | J. Sakulich, H. M. Poulos, R. G. Gatewood, K. A. Wogan, C. Marks, A. H. Taylor | 2022 | Sakulich, J., Poulos, H.M., Gatewood, R.G., Wogan, K.A., Marks, C., and Taylor, A.H., 2022, Low-severity wildfire shifts mixed conifer forests toward historical stand structure in Guadalupe Mountains National Park, Texas, USA: Fire, v. 5, no. 4, article 119, at https://doi.org/10.3390/fire5040119. |
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Differences in land ownership, fire management objectives and source data matter—A reply to Hanson and Odion (2014) | H. D. Safford, J. D. Miller, B. M. Collins | 2015 | Safford, H.D., Miller, J.D., and Collins, B.M., 2015, Differences in land ownership, fire management objectives and source data matter—A reply to Hanson and Odion (2014): International Journal of Wildland Fire, v. 24, no. 2, p. 286–293, at https://doi.org/10.1071/WF14013. |
Temporal and spatial patterns of fire regime disruption in conifer forests of western North America | J. E. Sáenz-Ceja, M. E. Mendoza | in press | Sáenz-Ceja, J.E., and Mendoza, M.E., in press, Temporal and spatial patterns of fire regime disruption in conifer forests of western North America: Physical Geography, at https://doi.org/10.1080/02723646.2024.2331292. |
What is the color when black is burned? Quantifying (re)burn severity using field and satellite remote sensing indices | S. J. Saberi, B. J. Harvey | 2023 | Saberi, S.J., and Harvey, B.J., 2023, What is the color when black is burned? Quantifying (re)burn severity using field and satellite remote sensing indices: Fire Ecology, v. 19, no. 1, article 24, at https://doi.org/10.1186/s42408-023-00178-3. |
Contrasting characteristics of atmospheric rivers and their impacts on 2016 and 2020 wildfire seasons over the western United States | J.-M. Ryoo, T. Park | 2023 | Ryoo, J.-M., and Park, T., 2023, Contrasting characteristics of atmospheric rivers and their impacts on 2016 and 2020 wildfire seasons over the western United States: Environmental Research Letters, v. 18, no. 7, article 074010, at https://doi.org/10.1088/1748-9326/acd948. |
Evaluating the factors responsible for post-fire water quality response in forests of the western USA | A. J. Rust, S. Saxe, J. McCray, C. C. Rhoades, T. S. Hogue | 2019 | Rust, A.J., Saxe, S., McCray, J., Rhoades, C.C., and Hogue, T.S., 2019, Evaluating the factors responsible for post-fire water quality response in forests of the western USA: International Journal of Wildland Fire, v. 28, no. 10, p. 769–784, at https://doi.org/10.1071/Wf18191. |
Climate drives episodic conifer establishment after fire in dry ponderosa pine forests of the Colorado Front Range, USA | M. T. Rother, T. T. Veblen | 2017 | Rother, M.T., and Veblen, T.T., 2017, Climate drives episodic conifer establishment after fire in dry ponderosa pine forests of the Colorado Front Range, USA: Forests, v. 8, no. 5, article 159, at https://doi.org/10.3390/f8050159. |
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Targeting sagebrush (Artemisia Spp.) restoration following wildfire with greater sage-grouse (Centrocercus Urophasianus) nest selection and survival models | C. L. Roth, S. T. O’Neil, P. S. Coates, M. A. Ricca, D. A. Pyke, C. L. Aldridge, J. A. Heinrichs, S. P. Espinosa, D. J. Delehanty | 2022 | Roth, C.L., O’Neil, S.T., Coates, P.S., Ricca, M.A., Pyke, D.A., Aldridge, C.L., Heinrichs, J.A., Espinosa, S.P., and Delehanty, D.J., 2022, Targeting sagebrush (Artemisia Spp.) restoration following wildfire with greater sage-grouse (Centrocercus Urophasianus) nest selection and survival models: Environmental Management, v. 70, p. 288–306, at https://doi.org/10.1007/s00267-022-01649-0. |
Northern expansion is not compensating for southern declines in North American boreal forests | R. Rotbarth, E. H. Van Nes, M. Scheffer, J. U. Jepsen, O. P. L. Vindstad, C. Xu, M. Holmgren | 2023 | Rotbarth, R., Van Nes, E.H., Scheffer, M., Jepsen, J.U., Vindstad, O.P.L., Xu, C., and Holmgren, M., 2023, Northern expansion is not compensating for southern declines in North American boreal forests: Nature Communications, v. 14, no. 1, article 3373 at https://doi.org/10.1038/s41467-023-39092-2. |
Characterizing forest dynamics with Landsat-derived phenology curves | M. B. Rose, N. N. Nagle | 2021 | Rose, M.B., and Nagle, N.N., 2021, Characterizing forest dynamics with Landsat-derived phenology curves: Remote Sensing, v. 13, no. 2, article 267, at https://doi.org/10.3390/rs13020267. |
Long-term biocrust responses to wildfires in Washington, USA | H. T. Root, J. Chan, J. Ponzetti, D. A. Pyke, B. McCune | 2023 | Root, H.T., Chan, J., Ponzetti, J., Pyke, D.A., and McCune, B., 2023, Long-term biocrust responses to wildfires in Washington, USA: American Journal of Botany, v. 110, no. 12, article e16261, at https://doi.org/10.1002/ajb2.16261. |
Biotic soil crust community composition 12–16 years after wildfires in Idaho, U.S.A. | H. T. Root, J. C. Brinda, E. K. Dodson | 2018 | Root, H.T., Brinda, J.C., and Dodson, E.K., 2018, Biotic soil crust community composition 12–16 years after wildfires in Idaho, U.S.A.: The Bryologist, v. 121, no. 3, p. 286–296, at https://doi.org/10.1639/0007-2745-121.3.286. |
Recovery of biological soil crust richness and cover 12–16 years after wildfires in Idaho, USA | H. T. Root, J. C. Brinda, E. Kyle Dodson | 2017 | Root, H.T., Brinda, J.C., and Kyle Dodson, E., 2017, Recovery of biological soil crust richness and cover 12–16 years after wildfires in Idaho, USA: Biogeosciences, v. 14, no. 17, p. 3957–3969, at https://doi.org/10.5194/bg-14-3957-2017. |
Deterministic and stochastic processes lead to divergence in plant communities 25 years after the 1988 Yellowstone fires | W. H. Romme, T. G. Whitby, D. B. Tinker, M. G. Turner | 2016 | Romme, W.H., Whitby, T.G., Tinker, D.B., and Turner, M.G., 2016, Deterministic and stochastic processes lead to divergence in plant communities 25 years after the 1988 Yellowstone fires: Ecological Monographs, v. 86, no. 3, p. 327–351, at https://doi.org/10.1002/ecm.1220. |
Quantifying fire-wide carbon emissions in interior Alaska using field measurements and Landsat imagery | B. M. Rogers, S. Veraverbeke, G. Azzari, C. I. Czimczik, S. R. Holden, G. O. Mouteva, F. Sedano, K. K. Treseder, J. T. Randerson | 2014 | Rogers, B.M., Veraverbeke, S., Azzari, G., Czimczik, C.I., Holden, S.R., Mouteva, G.O., Sedano, F., Treseder, K.K., and Randerson, J.T., 2014, Quantifying fire-wide carbon emissions in interior Alaska using field measurements and Landsat imagery: Journal of Geophysical Research—Biogeosciences, v. 119, no. 8, p. 1608–1629, at https://doi.org/10.1002/2014JG002657. |
SCaMF-RM—A fused high-resolution land cover product of the Rocky Mountains | N. Rodríguez-Jeangros, A. S. Hering, T. Kaiser, J. E. McCray | 2017 | Rodríguez-Jeangros, N., Hering, A.S., Kaiser, T., and McCray, J.E., 2017, SCaMF-RM—A fused high-resolution land cover product of the Rocky Mountains: Remote Sensing, v. 9, no. 10, article 1015, at https://doi.org/10.3390/rs9101015. |
Analysis of anthropogenic, climatological, and morphological influences on dissolved organic matter in Rocky Mountain streams | N. Rodríguez-Jeangros, A. Hering, J. McCray | 2018 | Rodríguez-Jeangros, N., Hering, A., and McCray, J., 2018, Analysis of anthropogenic, climatological, and morphological influences on dissolved organic matter in Rocky Mountain streams: Water, v. 10, no. 4, article 534, at https://doi.org/10.3390/w10040534. |
Using multi-decadal satellite records to identify environmental drivers of fire severity across vegetation types | D. Rodriguez-Cubillo, G. J. Jordan, G. J. Williamson | 2022 | Rodriguez-Cubillo, D., Jordan, G.J., and Williamson, G.J., 2022, Using multi-decadal satellite records to identify environmental drivers of fire severity across vegetation types: Remote Sensing in Earth Systems Sciences, v. 5, no. 3, p. 165–184, at https://doi.org/10.1007/s41976-022-00070-9. |
Wildfire activity and land use drove 20th-century changes in forest cover in the Colorado Front Range | K. C. Rodman, T. T. Veblen, S. Saraceni, T. B. Chapman | 2019 | Rodman, K.C., Veblen, T.T., Saraceni, S., and Chapman, T.B., 2019, Wildfire activity and land use drove 20th-century changes in forest cover in the Colorado Front Range: Ecosphere, v. 10, no. 2, article e02594, at https://doi.org/10.1002/ecs2.2594. |
Limitations to recovery following wildfire in dry forests of southern Colorado and northern New Mexico, USA | K. C. Rodman, T. T. Veblen, T. B. Chapman, M. T. Rother, A. P. Wion, M. D. Redmond | 2020 | Rodman, K.C., Veblen, T.T., Chapman, T.B., Rother, M.T., Wion, A.P., and Redmond, M.D., 2020, Limitations to recovery following wildfire in dry forests of southern Colorado and northern New Mexico, USA: Ecological Applications, v. 30, no. 1, article e02001, at https://doi.org/10.1002/eap.2001. |
A changing climate is snuffing out post-fire recovery in montane forests | K. C. Rodman, T. T. Veblen, M. A. Battaglia, M. E. Chambers, P. J. Fornwalt, Z. A. Holden, T. E. Kolb, J. R. Ouzts, M. T. Rother | 2020 | Rodman, K.C., Veblen, T.T., Battaglia, M.A., Chambers, M.E., Fornwalt, P.J., Holden, Z.A., Kolb, T.E., Ouzts, J.R., and Rother, M.T., 2020, A changing climate is snuffing out post-fire recovery in montane forests: Global Ecology and Biogeography, v. 29, no. 11, p. 2039–2051, at https://doi.org/10.1111/geb.13174. |
A trait-based approach to assessing resistance and resilience to wildfire in two iconic North American conifers | K. C. Rodman, T. T. Veblen, R. A. Andrus, N. J. Enright, J. B. Fontaine, A. D. Gonzalez, M. D. Redmond, A. P. Wion | 2020 | Rodman, K.C., Veblen, T.T., Andrus, R.A., Enright, N.J., Fontaine, J.B., Gonzalez, A.D., Redmond, M.D., and Wion, A.P., 2020, A trait-based approach to assessing resistance and resilience to wildfire in two iconic North American conifers: Journal of Ecology, v. 109, no. 1, p. 313–326, at https://doi.org/10.1111/1365-2745.13480. |
Refuge-yeah or refuge-nah? Predicting locations of forest resistance and recruitment in a fiery world | K. C. Rodman, K. T. Davis, S. A. Parks, T. B. Chapman, J. D. Coop, J. M. Iniguez, J. P. Roccaforte, A. J. Sánchez Meador, J. D. Springer, C. S. Stevens-Rumann, M. T. Stoddard, A. E. M. Waltz, T. N. Wasserman | 2023 | Rodman, K.C., Davis, K.T., Parks, S.A., Chapman, T.B., Coop, J.D., Iniguez, J.M., Roccaforte, J.P., Sánchez Meador, A.J., Springer, J.D., et al., 2023, Refuge-yeah or refuge-nah? Predicting locations of forest resistance and recruitment in a fiery world: Global Change Biology, v. 29, no. 24, p. 7029–7050, at https://doi.org/10.1111/gcb.16939. |
Patterns and drivers of recent land cover change on two trailing-edge forest landscapes | K. C. Rodman, J. E. Crouse, J. J. Donager, D. W. Huffman, A. J. Sánchez Meador | 2022 | Rodman, K.C., Crouse, J.E., Donager, J.J., Huffman, D.W., and Sánchez Meador, A.J., 2022, Patterns and drivers of recent land cover change on two trailing-edge forest landscapes: Forest Ecology and Management, v. 521, article 120449, at https://doi.org/10.1016/j.foreco.2022.120449. |
Rocky Mountain forests are poised to recover following bark beetle outbreaks but with altered composition | K. C. Rodman, R. A. Andrus, A. R. Carlson, T. A. Carter, T. B. Chapman, J. D. Coop, P. J. Fornwalt, N. S. Gill, B. J. Harvey, A. E. Hoffman, K. C. Kelsey, D. Kulakowski, D. C. Laughlin, J. E. Morris, J. F. Negrón, K. M. Nigro, G. S. Pappas, M. D. Redmond, C. C. Rhoades, M. E. Rocca, Z. H. Schapira, J. S. Sibold, C. S. Stevens-Rumann, T. T. Veblen, J. Wang, X. Zhang, S. J. Hart | 2022 | Rodman, K.C., Andrus, R.A., Carlson, A.R., Carter, T.A., Chapman, T.B., Coop, J.D., Fornwalt, P.J., Gill, N.S., Harvey, B.J., et al., 2022, Rocky Mountain forests are poised to recover following bark beetle outbreaks but with altered composition: Journal of Ecology, v. 110, no. 12, p. 2929–2949, at https://doi.org/10.1111/1365-2745.13999. |
Effects of bark beetle outbreaks on forest landscape pattern in the Southern Rocky Mountains, U.S.A. | K. C. Rodman, R. A. Andrus, C. L. Butkiewicz, T. B. Chapman, N. S. Gill, B. J. Harvey, D. Kulakowski, N. J. Tutland, T. T. Veblen, S. J. Hart | 2021 | Rodman, K.C., Andrus, R.A., Butkiewicz, C.L., Chapman, T.B., Gill, N.S., Harvey, B.J., Kulakowski, D., Tutland, N.J., Veblen, T.T., and Hart, S.J., 2021, Effects of bark beetle outbreaks on forest landscape pattern in the Southern Rocky Mountains, U.S.A.: Remote Sensing, v. 13, no. 6, article 1089, at https://doi.org/10.3390/rs13061089. |
The late Holocene history of Lake Cahuilla—Two thousand years of repeated fillings within the Salton Trough, Imperial Valley, California | T. K. Rockwell, A. J. Meltzner, E. C. Haaker, D. Madugo | 2022 | Rockwell, T.K., Meltzner, A.J., Haaker, E.C., and Madugo, D., 2022, The late Holocene history of Lake Cahuilla—Two thousand years of repeated fillings within the Salton Trough, Imperial Valley, California: Quaternary Science Reviews, v. 282, article 107456, at https://doi.org/10.1016/j.quascirev.2022.107456. |
Differential impacts of wildfire on the population dynamics of an old-forest species | J. T. Rockweit, A. B. Franklin, P. C. Carlson | 2017 | Rockweit, J.T., Franklin, A.B., and Carlson, P.C., 2017, Differential impacts of wildfire on the population dynamics of an old-forest species: Ecology, v. 98, no. 6, p. 1574–1582, at https://doi.org/10.1002/ecy.1805. |
Estimating evapotranspiration change due to forest treatment and fire at the basin scale in the Sierra Nevada, California | J. W. Roche, M. L. Goulden, R. C. Bales | 2018 | Roche, J.W., Goulden, M.L., and Bales, R.C., 2018, Estimating evapotranspiration change due to forest treatment and fire at the basin scale in the Sierra Nevada, California: Ecohydrology, v. 11, no. 7, article e1978, at https://doi.org/10.1002/eco.1978. |
A century of changing flows—Forest management changed flow magnitudes and warming advanced the timing of flow in a southwestern US river | M. D. Robles, D. S. Turner, J. A. Haney | 2017 | Robles, M.D., Turner, D.S., and Haney, J.A., 2017, A century of changing flows—Forest management changed flow magnitudes and warming advanced the timing of flow in a southwestern US river: PLoS ONE, v. 12, no. 11, article e0187875, at https://doi.org/10.1371/journal.pone.0187875. |
Effects of climate variability and accelerated forest thinning on watershed-scale runoff in southwestern USA ponderosa pine forests | M. D. Robles, R. M. Marshall, F. O'Donnell, E. B. Smith, J. A. Haney, D. F. Gori | 2014 | Robles, M.D., Marshall, R.M., O'Donnell, F., Smith, E.B., Haney, J.A., and Gori, D.F., 2014, Effects of climate variability and accelerated forest thinning on watershed-scale runoff in southwestern USA ponderosa pine forests: PLoS ONE, v. 9, no. 10, article A1819, at https://doi.org/10.1371/journal.pone.0111092. |
A geospatial dataset providing first-order indicators of wildfire risks to water supply in Canada and Alaska | F. N. Robinne | 2020 | Robinne, F.N., 2020, A geospatial dataset providing first-order indicators of wildfire risks to water supply in Canada and Alaska: Data Brief, v. 29, article 105171, at https://doi.org/10.1016/j.dib.2020.105171. |
A synthesis of post-fire Burned Area Reports from 1972 to 2009 for western US Forest Service lands—Trends in wildfire characteristics and post-fire stabilisation treatments and expenditures | P. R. Robichaud, H. Rhee, S. A. Lewis | 2014 | Robichaud, P.R., Rhee, H., and Lewis, S.A., 2014, A synthesis of post-fire Burned Area Reports from 1972 to 2009 for western US Forest Service lands—Trends in wildfire characteristics and post-fire stabilisation treatments and expenditures: International Journal of Wildland Fire, v. 23, no. 7, p. 929–944, at https://doi.org/10.1071/WF13192. |
Leveraging the potential of nature to meet net zero greenhouse gas emissions in Washington State | J. C. Robertson, K. V. Randrup, E. R. Howe, M. J. Case, P. S. Levin | 2021 | Robertson, J.C., Randrup, K.V., Howe, E.R., Case, M.J., and Levin, P.S., 2021, Leveraging the potential of nature to meet net zero greenhouse gas emissions in Washington State: PeerJ, v. 9, article e11802, at https://doi.org/10.7717/peerj.11802. |
Tracking spatial regimes in animal communities—Implications for resilience-based management | C. P. Roberts, D. R. Uden, C. R. Allen, D. G. Angeler, L. A. Powell, B. W. Allred, M. O. Jones, J. D. Maestas, D. Twidwell | 2022 | Roberts, C.P., Uden, D.R., Allen, C.R., Angeler, D.G., Powell, L.A., Allred, B.W., Jones, M.O., Maestas, J.D., and Twidwell, D., 2022, Tracking spatial regimes in animal communities—Implications for resilience-based management: Ecological Indicators, v. 136, article 108567, at https://doi.org/10.1016/j.ecolind.2022.108567. |
Fire legacies in eastern ponderosa pine forests | C. P. Roberts, V. M. Donovan, C. L. Wonkka, L. A. Powell, C. R. Allen, D. G. Angeler, D. A. Wedin, D. Twidwell | 2019 | Roberts, C.P., Donovan, V.M., Wonkka, C.L., Powell, L.A., Allen, C.R., Angeler, D.G., Wedin, D.A., and Twidwell, D., 2019, Fire legacies in eastern ponderosa pine forests: Ecology and Evolution, v. 9, no. 4, p. 1869–1879, at https://doi.org/10.1002/ece3.4879. |
Fire legacies, heterogeneity, and the importance of mixed-severity fire in ponderosa pine savannas | C. P. Roberts, V. M. Donovan, S. M. Nodskov, E. B. Keele, C. R. Allen, D. A. Wedin, D. Twidwell | 2020 | Roberts, C.P., Donovan, V.M., Nodskov, S.M., Keele, E.B., Allen, C.R., Wedin, D.A., and Twidwell, D., 2020, Fire legacies, heterogeneity, and the importance of mixed-severity fire in ponderosa pine savannas: Forest Ecology and Management, v. 459, article 117853, at https://doi.org/10.1016/j.foreco.2019.117853. |
Patterns and trends in burned area and fire severity from 1984 to 2010 in the Sierra de San Pedro Martir, Baja California, Mexico | H. Rivera-Huerta, H. D. Safford, J. D. Miller | 2016 | Rivera-Huerta, H., Safford, H.D., and Miller, J.D., 2016, Patterns and trends in burned area and fire severity from 1984 to 2010 in the Sierra de San Pedro Martir, Baja California, Mexico: Fire Ecology, v. 12, no. 1, p. 52–72, at https://doi.org/10.4996/fireecology.1201052. |
A model-based framework to evaluate alternative wildfire suppression strategies | K. L. Riley, M. P. Thompson, J. H. Scott, J. W. Gilbertson-Day | 2018 | Riley, K.L., Thompson, M.P., Scott, J.H., and Gilbertson-Day, J.W., 2018, A model-based framework to evaluate alternative wildfire suppression strategies: Resources, v. 7, no. 1, article 4, at https://doi.org/10.3390/resources7010004. |
The relationship of large fire occurrence with drought and fire danger indices in the western USA, 1984–2008—The role of temporal scale | K. L. Riley, J. T. Abatzoglou, I. C. Grenfell, A. E. Klene, F. A. Heinsch | 2013 | Riley, K.L., Abatzoglou, J.T., Grenfell, I.C., Klene, A.E., and Heinsch, F.A., 2013, The relationship of large fire occurrence with drought and fire danger indices in the western USA, 1984–2008—The role of temporal scale: International Journal of Wildland Fire, v. 22, no. 7, p. 894–909, at https://doi.org/10.1071/WF12149. |
Influence of management and precipitation on carbon fluxes in great plains grasslands | M. Rigge, B. Wylie, L. Zhang, S. P. Boyte | 2013 | Rigge, M., Wylie, B., Zhang, L., and Boyte, S.P., 2013, Influence of management and precipitation on carbon fluxes in great plains grasslands: Ecological Indicators, v. 34, no. 0, p. 590–599, at https://doi.org/10.1016/j.ecolind.2013.06.028. |
Monitoring the status of forests and rangelands in the western United States using ecosystem performance anomalies | M. Rigge, B. Wylie, Y. Gu, J. Belnap, K. Phuyal, L. Tieszen | 2013 | Rigge, M., Wylie, B., Gu, Y., Belnap, J., Phuyal, K., and Tieszen, L., 2013, Monitoring the status of forests and rangelands in the western United States using ecosystem performance anomalies: International Journal of Remote Sensing, v. 34, no. 11, p. 4049–4068, at https://doi.org/10.1080/01431161.2013.772311. |
Projected change in rangeland fractional component cover across the sagebrush biome under climate change through 2085 | M. Rigge, H. Shi, K. Postma | 2021 | Rigge, M., Shi, H., and Postma, K., 2021, Projected change in rangeland fractional component cover across the sagebrush biome under climate change through 2085: Ecosphere, v. 12, no. 6, article e03538, at https://doi.org/10.1002/ecs2.3538. |
Long-term trajectories of fractional component change in the northern Great Basin, USA | M. Rigge, H. Shi, C. Homer, P. Danielson, B. Granneman | 2019 | Rigge, M., Shi, H., Homer, C., Danielson, P., and Granneman, B., 2019, Long-term trajectories of fractional component change in the northern Great Basin, USA: Ecosphere, v. 10, no. 6, article e02762, at https://doi.org/10.1002/ecs2.2762. |
Ecological potential fractional component cover based on long-term satellite observations across the western United States | M. Rigge, D. Meyer, B. Bunde | 2021 | Rigge, M., Meyer, D., and Bunde, B., 2021, Ecological potential fractional component cover based on long-term satellite observations across the western United States: Ecological Indicators, v. 133, article 108447, at https://doi.org/10.1016/j.ecolind.2021.108447. |
Rangeland fractional components across the western United States from 1985 to 2018 | M. Rigge, C. Homer, H. Shi, D. Meyer, B. Bunde, B. Granneman, K. Postma, P. Danielson, A. Case, G. Xian | 2021 | Rigge, M., Homer, C., Shi, H., Meyer, D., Bunde, B., Granneman, B., Postma, K., Danielson, P., Case, A., and Xian, G., 2021, Rangeland fractional components across the western United States from 1985 to 2018: Remote Sensing, v. 13, no. 4, article 813, at https://doi.org/10.3390/rs13040813. |
Quantifying western U.S. rangelands as fractional components with multi-resolution remote sensing and in situ data | M. Rigge, C. Homer, L. Cleeves, D. K. Meyer, B. Bunde, H. Shi, G. Xian, S. Schell, M. Bobo | 2020 | Rigge, M., Homer, C., Cleeves, L., Meyer, D.K., Bunde, B., Shi, H., Xian, G., Schell, S., and Bobo, M., 2020, Quantifying western U.S. rangelands as fractional components with multi-resolution remote sensing and in situ data: Remote Sensing, v. 12, no. 3, article 412, at https://doi.org/10.3390/rs12030412. |
A potential framework for allocating National Park Service budgets | D. B. Rideout, Y. Wei, N. Kernohan, A. G. Kirsch | 2022 | Rideout, D.B., Wei, Y., Kernohan, N., and Kirsch, A.G., 2022, A potential framework for allocating National Park Service budgets: Frontiers in Forests and Global Change, v. 5, article 716569, at https://doi.org/10.3389/ffgc.2022.716569. |
Wildfires increase concentrations of hazardous air pollutants in downwind communities | R. B. Rice, K. Boaggio, N. E. Olson, K. M. Foley, C. P. Weaver, J. D. Sacks, S. R. McDow, A. L. Holder, S. D. LeDuc | 2023 | Rice, R.B., Boaggio, K., Olson, N.E., Foley, K.M., Weaver, C.P., Sacks, J.D., McDow, S.R., Holder, A.L., and LeDuc, S.D., 2023, Wildfires increase concentrations of hazardous air pollutants in downwind communities: Environmental Science & Technology, v. 57, no. 50, p. 21235–21248, at https://doi.org/10.1021/acs.est.3c04153. |
A conservation planning tool for greater sage-grouse using indices of species distribution, resilience, and resistance | M. A. Ricca, P. S. Coates, K. B. Gustafson, B. E. Brussee, J. C. Chambers, S. P. Espinosa, S. C. Gardner, S. Lisius, P. Ziegler, D. J. Delehanty, M. L. Casazza | 2018 | Ricca, M.A., Coates, P.S., Gustafson, K.B., Brussee, B.E., Chambers, J.C., Espinosa, S.P., Gardner, S.C., Lisius, S., Ziegler, P., et al., 2018, A conservation planning tool for greater sage-grouse using indices of species distribution, resilience, and resistance: Ecological Applications, v. 28, no. 4, p. 878–896, at https://doi.org/10.1002/eap.1690. |
Integrating ecosystem resilience and resistance into decision support tools for multi-scale population management of a sagebrush indicator species | M. A. Ricca, P. S. Coates | 2020 | Ricca, M.A., and Coates, P.S., 2020, Integrating ecosystem resilience and resistance into decision support tools for multi-scale population management of a sagebrush indicator species: Frontiers in Ecology and Evolution, v. 7, article 493, at https://doi.org/10.3389/fevo.2019.00493. |
Modeling herbaceous biomass for grazing and fire risk management | E. C. Rhodes, D. R. Tolleson, J. P. Angerer | 2022 | Rhodes, E.C., Tolleson, D.R., and Angerer, J.P., 2022, Modeling herbaceous biomass for grazing and fire risk management: Land, v. 11, no. 10, article 1769, at https://doi.org/10.3390/land11101769. |
Use of geostatistical models to evaluate landscape and stream network controls on post-fire stream nitrate concentrations | A. E. Rhea, T. P. Covino, C. C. Rhoades, A. C. Brooks | 2022 | Rhea, A.E., Covino, T.P., Rhoades, C.C., and Brooks, A.C., 2022, Use of geostatistical models to evaluate landscape and stream network controls on post-fire stream nitrate concentrations: Hydrological Processes, v. 36, no. 9, article e14689, at https://doi.org/10.1002/hyp.14689. |
Reduced N-limitation and increased in-stream productivity of autotrophic biofilms 5 and 15 years after severe wildfire | A. E. Rhea, T. P. Covino, C. C. Rhoades | 2021 | Rhea, A.E., Covino, T.P., and Rhoades, C.C., 2021, Reduced N-limitation and increased in-stream productivity of autotrophic biofilms 5 and 15 years after severe wildfire: Journal of Geophysical Research—Biogeosciences, v. 126, no. 9, article e2020JG006095, at https://doi.org/10.1029/2020JG006095. |
Wildfire-induced shifts in groundwater discharge to streams identified with paired air and stream water temperature analyses | D. M. Rey, M. A. Briggs, M. A. Walvoord, B. A. Ebel | 2023 | Rey, D.M., Briggs, M.A., Walvoord, M.A., and Ebel, B.A., 2023, Wildfire-induced shifts in groundwater discharge to streams identified with paired air and stream water temperature analyses: Journal of Hydrology, v. 619, article 129272, at https://doi.org/10.1016/j.jhydrol.2023.129272. |
A spectral–spatial method for mapping fire severity using morphological attribute profiles | X. Ren, X. Yu, Y. Wang | 2023 | Ren, X., Yu, X., and Wang, Y., 2023, A spectral–spatial method for mapping fire severity using morphological attribute profiles: Remote Sensing, v. 15, no. 3, article 699, at https://doi.org/10.3390/rs15030699. |
Bark beetle effects on fire regimes depend on underlying fuel modifications in semiarid systems | J. Ren, E. J. Hanan, J. A. Hicke, C. A. Kolden, J. T. Abatzoglou, C. N. L. Tague, R. R. Bart, M. C. Kennedy, M. Liu, J. C. Adam | 2023 | Ren, J., Hanan, E.J., Hicke, J.A., Kolden, C.A., Abatzoglou, J.T., Tague, C.N.L., Bart, R.R., Kennedy, M.C., Liu, M., and Adam, J.C., 2023, Bark beetle effects on fire regimes depend on underlying fuel modifications in semiarid systems: Journal of Advances in Modeling Earth Systems, v. 15, no. 1, article e2022MS003073, at https://doi.org/10.1029/2022MS003073. |
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Quantifying pinyon-juniper reduction within North America's Sagebrush Ecosystem | J. R. Reinhardt, S. Filippelli, M. Falkowski, B. Allred, J. D. Maestas, J. C. Carlson, D. E. Naugle | 2020 | Reinhardt, J.R., Filippelli, S., Falkowski, M., Allred, B., Maestas, J.D., Carlson, J.C., and Naugle, D.E., 2020, Quantifying pinyon-juniper reduction within North America's Sagebrush Ecosystem: Rangeland Ecology & Management, v. 73, no. 3, p. 420–432, at https://doi.org/10.1016/j.rama.2020.01.002. |
The potential of multispectral imagery and 3D point clouds from unoccupied aerial systems (UAS) for monitoring forest structure and the impacts of wildfire in Mediterranean-climate forests | S. Reilly, M. L. Clark, L. P. Bentley, C. Matley, E. Piazza, I. Oliveras Menor | 2021 | Reilly, S., Clark, M.L., Bentley, L.P., Matley, C., Piazza, E., and Oliveras Menor, I., 2021, The potential of multispectral imagery and 3D point clouds from unoccupied aerial systems (UAS) for monitoring forest structure and the impacts of wildfire in Mediterranean-climate forests: Remote Sensing, v. 13, no. 19, article 3810, at https://doi.org/10.3390/rs13193810. |
Characterizing post-fire delayed tree mortality with remote sensing—Sizing up the elephant in the room | M. J. Reilly, A. Zuspan, Z. Yang | 2023 | Reilly, M.J., Zuspan, A., and Yang, Z., 2023, Characterizing post-fire delayed tree mortality with remote sensing—Sizing up the elephant in the room: Fire Ecology, v. 19, no. 1, article 64, at https://doi.org/10.1186/s42408-023-00223-1. |
Cascadia burning—The historic, but not historically unprecedented, 2020 wildfires in the Pacific Northwest, USA | M. J. Reilly, A. Zuspan, J. S. Halofsky, C. Raymond, A. McEvoy, A. W. Dye, D. C. Donato, J. B. Kim, B. E. Potter, N. Walker, R. J. Davis, C. J. Dunn, D. M. Bell, M. J. Gregory, J. D. Johnston, B. J. Harvey, J. E. Halofsky, B. K. Kerns | 2022 | Reilly, M.J., Zuspan, A., Halofsky, J.S., Raymond, C., McEvoy, A., Dye, A.W., Donato, D.C., Kim, J.B., Potter, B.E., et al., 2022, Cascadia burning—The historic, but not historically unprecedented, 2020 wildfires in the Pacific Northwest, USA: Ecosphere, v. 13, no. 6, article e4070, at https://doi.org/10.1002/ecs2.4070. |
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Range-wide population structure and dynamics of a serotinous conifer, knobcone pine (Pinus attenuata L.), under an anthropogenically-altered disturbance regime | M. J. Reilly, V. J. Monleon, E. S. Jules, R. J. Butz | 2019 | Reilly, M.J., Monleon, V.J., Jules, E.S., and Butz, R.J., 2019, Range-wide population structure and dynamics of a serotinous conifer, knobcone pine (Pinus attenuata L.), under an anthropogenically-altered disturbance regime: Forest Ecology and Management, v. 441, p. 182–191, at https://doi.org/10.1016/j.foreco.2019.03.017. |
Cumulative effects of wildfires on forest dynamics in the eastern Cascade Mountains, USA | M. J. Reilly, M. Elia, T. A. Spies, M. J. Gregory, G. Sanesi, R. Lafortezza | 2018 | Reilly, M.J., Elia, M., Spies, T.A., Gregory, M.J., Sanesi, G., and Lafortezza, R., 2018, Cumulative effects of wildfires on forest dynamics in the eastern Cascade Mountains, USA: Ecological Applications, v. 28, no. 2, p. 291–308, at https://doi.org/10.1002/eap.1644. |
Contemporary patterns of fire extent and severity in forests of the Pacific Northwest, USA (1985–2010) | M. J. Reilly, C. J. Dunn, G. W. Meigs, T. A. Spies, R. E. Kennedy, J. D. Bailey, K. Briggs | 2017 | Reilly, M.J., Dunn, C.J., Meigs, G.W., Spies, T.A., Kennedy, R.E., Bailey, J.D., and Briggs, K., 2017, Contemporary patterns of fire extent and severity in forests of the Pacific Northwest, USA (1985–2010): Ecosphere, v. 8, no. 3, article e01695, at https://doi.org/10.1002/ecs2.1695. |
Quantifying soil carbon loss and uncertainty from a peatland wildfire using multi-temporal LiDAR | A. D. Reddy, T. J. Hawbaker, F. Wurster, Z. Zhu, S. Ward, D. Newcomb, R. Murray | 2015 | Reddy, A.D., Hawbaker, T.J., Wurster, F., Zhu, Z., Ward, S., Newcomb, D., and Murray, R., 2015, Quantifying soil carbon loss and uncertainty from a peatland wildfire using multi-temporal LiDAR: Remote Sensing of Environment, v. 170, p. 306–316, at https://doi.org/10.1016/j.rse.2015.09.017. |
Unequal effects of wildfire exposure on infant health by maternal education, 1995–2020 | E. Rauscher, X. Cao | 2024 | Rauscher, E., and Cao, X., 2024, Unequal effects of wildfire exposure on infant health by maternal education, 1995–2020: RSF—The Russell Sage Foundation Journal of the Social Sciences, v. 10, no. 1, p. 255–274, at https://doi.org/10.7758/RSF.2024.10.1.11. |
Global burned area and biomass burning emissions from small fires | J. T. Randerson, Y. Chen, G. R. Van Der Werf, B. M. Rogers, D. C. Morton | 2012 | Randerson, J.T., Chen, Y., Van Der Werf, G.R., Rogers, B.M., and Morton, D.C., 2012, Global burned area and biomass burning emissions from small fires: Journal of Geophysical Research—Biogeosciences, v. 117, no. 4, article G04012, at https://doi.org/10.1029/2012JG002128. |
Widespread regeneration failure in forests of Greater Yellowstone under scenarios of future climate and fire | W. Rammer, K. H. Braziunas, W. D. Hansen, Z. Ratajczak, A. L. Westerling, M. G. Turner, R. Seidl | 2021 | Rammer, W., Braziunas, K.H., Hansen, W.D., Ratajczak, Z., Westerling, A.L., Turner, M.G., and Seidl, R., 2021, Widespread regeneration failure in forests of Greater Yellowstone under scenarios of future climate and fire: Global Change Biology, v. 27, no. 3, p. 4339–4351, at https://doi.org/10.1111/gcb.15726. |
Rapid growth of the US wildland-urban interface raises wildfire risk | V. C. Radeloff, D. P. Helmers, H. A. Kramer, M. H. Mockrin, P. M. Alexandre, A. Bar-Massada, V. Butsic, T. J. Hawbaker, S. Martinuzzi, A. D. Syphard, S. I. Stewart | 2018 | Radeloff, V.C., Helmers, D.P., Kramer, H.A., Mockrin, M.H., Alexandre, P.M., Bar-Massada, A., Butsic, V., Hawbaker, T.J., Martinuzzi, S., et al., 2018, Rapid growth of the US wildland-urban interface raises wildfire risk: Proceedings of the National Academy of Sciences of the United States of America, v. 115, no. 13, p. 3314–3319, at https://doi.org/10.1073/pnas.1718850115. |
Human and infrastructure exposure to large wildfires in the United States | A. Modaresi Rad, J. T. Abatzoglou, J. Kreitler, M. R. Alizadeh, A. AghaKouchak, N. Hudyma, N. J. Nauslar, M. Sadegh | 2023 | Modaresi Rad, A., Abatzoglou, J.T., Kreitler, J., Alizadeh, M.R., AghaKouchak, A., Hudyma, N., Nauslar, N.J., and Sadegh, M., 2023, Human and infrastructure exposure to large wildfires in the United States: Nature Sustainability, v. 6, p. 1343–1351, at https://doi.org/10.1038/s41893-023-01163-z. |
Prescribed fires, smoke exposure, and hospital utilization among heart failure patients | H. Raab, J. Moyer, S. Afrin, F. Garcia-Menendez, C. K. Ward-Caviness | 2023 | Raab, H., Moyer, J., Afrin, S., Garcia-Menendez, F., and Ward-Caviness, C.K., 2023, Prescribed fires, smoke exposure, and hospital utilization among heart failure patients: Environmental Health, v. 22, no. 1, article 86, at https://doi.org/10.1186/s12940-023-01032-4. |
The geography of social vulnerability and wildfire occurrence (1984–2018) in the conterminous USA | R. L. Schumann, III, C. T. Emrich, V. Butsic, M. H. Mockrin, Y. Zhou, C. Johnson Gaither, O. Price, A. D. Syphard, J. Whittaker, S. K. Aksha | 2024 | Schumann, R.L., III, Emrich, C.T., Butsic, V., Mockrin, M.H., Zhou, Y., Johnson Gaither, C., Price, O., Syphard, A.D., Whittaker, J., and Aksha, S.K., 2024, The geography of social vulnerability and wildfire occurrence (1984–2018) in the conterminous USA: Natural Hazards, v. 120, p. 4297–4327, at https://doi.org/10.1007/s11069-023-06367-2. |
Improving fire severity analysis in Mediterranean environments—A comparative study of eeMETRIC and SSEBop Landsat-based evapotranspiration models | C. Quintano, A. Fernández-Manso, J. M. Fernández-Guisuraga, D. A. Roberts | 2024 | Quintano, C., Fernández-Manso, A., Fernández-Guisuraga, J.M., and Roberts, D.A., 2024, Improving fire severity analysis in Mediterranean environments—A comparative study of eeMETRIC and SSEBop Landsat-based evapotranspiration models: Remote Sensing, v. 16, no. 2, article 361, at https://doi.org/10.3390/rs16020361. |
Higher burn severity stimulates postfire vegetation and carbon recovery in California | L. Qiu, L. Fan, L. Sun, Z. Zeng, L. Feng, C. Yue, C. Zheng | 2023 | Qiu, L., Fan, L., Sun, L., Zeng, Z., Feng, L., Yue, C., and Zheng, C., 2023, Higher burn severity stimulates postfire vegetation and carbon recovery in California: Agricultural and Forest Meteorology, v. 342, article 109750, at https://doi.org/10.1016/j.agrformet.2023.109750. |
Object-based validation of a Sentinel-2 burned area product using ground-based burn polygons | L. Pulvirenti, G. Squicciarino, D. Negro, S. Puca | 2023 | Pulvirenti, L., Squicciarino, G., Negro, D., and Puca, S., 2023, Object-based validation of a Sentinel-2 burned area product using ground-based burn polygons: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, v. 16, p. 9154–9163, at https://doi.org/10.1109/jstars.2023.3316303. |
Combined use of data from avian surveys along the Pacific Crest Trail with biodiversity repositories to model habitat suitability throughout northern California | H. N. Pruhsmeier, M. C. McGrann, J. Graham | 2021 | Pruhsmeier, H.N., McGrann, M.C., and Graham, J., 2021, Combined use of data from avian surveys along the Pacific Crest Trail with biodiversity repositories to model habitat suitability throughout northern California: IdeaFest—Interdisciplinary Journal of Creative Works and Research from Humboldt State University, v. 5, article 3, at https://digitalcommons.humboldt.edu/ideafest/vol5/iss1/3/. |
The impacts of wildfire characteristics and employment on the adaptive management strategies in the Intermountain West | L. Prudencio, R. Choi, E. Esplin, M. Ge, N. Gillard, J. Haight, P. Belmont, C. Flint | 2018 | Prudencio, L., Choi, R., Esplin, E., Ge, M., Gillard, N., Haight, J., Belmont, P., and Flint, C., 2018, The impacts of wildfire characteristics and employment on the adaptive management strategies in the Intermountain West: Fire, v. 1, no. 3, article 46, at https://doi.org/10.3390/fire1030046. |
Landscape conservation forecasting for data-poor at-risk species on western public lands, United States | L. Provencher, K. Badik, T. Anderson, J. Tuhy, D. Fletcher, E. York, S. Byer | 2021 | Provencher, L., Badik, K., Anderson, T., Tuhy, J., Fletcher, D., York, E., and Byer, S., 2021, Landscape conservation forecasting for data-poor at-risk species on western public lands, United States: Climate, v. 9, no. 5, article 79, at https://doi.org/10.3390/cli9050079. |
The REBURN model—Simulating system-level forest succession and wildfire dynamics | S. J. Prichard, R. B. Salter, P. F. Hessburg, N. A. Povak, R. W. Gray | 2023 | Prichard, S.J., Salter, R.B., Hessburg, P.F., Povak, N.A., and Gray, R.W., 2023, The REBURN model—Simulating system-level forest succession and wildfire dynamics: Fire Ecology, v. 19, no. 1, article 38, at https://doi.org/10.1186/s42408-023-00190-7. |
Fuel treatments and landform modify landscape patterns of burn severity in an extreme fire event | S. J. Prichard, M. C. Kennedy | 2014 | Prichard, S.J., and Kennedy, M.C., 2014, Fuel treatments and landform modify landscape patterns of burn severity in an extreme fire event: Ecological Applications, v. 24, no. 3, p. 571–590, at https://doi.org/10.1890/13-0343.1. |
Modeling of fire spread in sagebrush steppe using FARSITE—An approach to improving input data and simulation accuracy | S. Price, M. J. Germino | 2022 | Price, S., and Germino, M.J., 2022, Modeling of fire spread in sagebrush steppe using FARSITE—An approach to improving input data and simulation accuracy: Fire Ecology, v. 18, no. 1, article 23, at https://doi.org/10.1186/s42408-022-00147-2. |
Non-native plant invasion after fire in western USA varies by functional type and with climate | J. S. Prevéy, C. S. Jarnevich, I. S. Pearse, S. M. Munson, J. T. Stevens, K. J. Barrett, J. D. Coop, M. A. Day, D. Firmage, P. J. Fornwalt, K. M. Haynes, J. D. Johnston, B. K. Kerns, M. A. Krawchuk, B. A. Miller, T. C. Nietupski, J. Roque, J. D. Springer, C. S. Stevens-Rumann, M. T. Stoddard, C. M. Tortorelli | 2024 | Prevéy, J.S., Jarnevich, C.S., Pearse, I.S., Munson, S.M., Stevens, J.T., Barrett, K.J., Coop, J.D., Day, M.A., Firmage, D., et al., 2024, Non-native plant invasion after fire in western USA varies by functional type and with climate: Biological Invasions, v. 26, p. 1157–1179, at https://doi.org/10.1007/s10530-023-03235-9. |
The character and changing frequency of extreme California fire weather | A. F. Prein, J. Coen, A. Jaye | 2022 | Prein, A.F., Coen, J., and Jaye, A., 2022, The character and changing frequency of extreme California fire weather: Journal of Geophysical Research—Atmospheres, v. 127, no. 9, article e2021JD035350, at https://doi.org/10.1029/2021jd035350. |
Observation of trends in biomass loss as a result of disturbance in the conterminous U.S.—1986–2004 | S. L. Powell, W. B. Cohen, R. E. Kennedy, S. P. Healey, C. Huang | 2014 | Powell, S.L., Cohen, W.B., Kennedy, R.E., Healey, S.P., and Huang, C., 2014, Observation of trends in biomass loss as a result of disturbance in the conterminous U.S.—1986–2004: Ecosystems, v. 17, no. 1, p. 142–157, at https://doi.org/10.1007/s10021-013-9713-9. |
Multi-scaled drivers of severity patterns vary across land ownerships for the 2013 Rim Fire, California | N. A. Povak, V. Kane, B. M. Collins, J. M. Lydersen, J. T. Kane | 2020 | Povak, N.A., Kane, V., Collins, B.M., Lydersen, J.M., and Kane, J.T., 2020, Multi-scaled drivers of severity patterns vary across land ownerships for the 2013 Rim Fire, California: Landscape Ecology, v. 35, no. 2, p. 293–318, at https://doi.org/10.1007/s10980-019-00947-z. |
Wildfire severity and postfire salvage harvest effects on long-term forest regeneration | N. A. Povak, D. J. Churchill, C. A. Cansler, P. F. Hessburg, V. R. Kane, J. T. Kane, J. A. Lutz, A. J. Larson | 2020 | Povak, N.A., Churchill, D.J., Cansler, C.A., Hessburg, P.F., Kane, V.R., Kane, J.T., Lutz, J.A., and Larson, A.J., 2020, Wildfire severity and postfire salvage harvest effects on long-term forest regeneration: Ecosphere, v. 11, no. 8, article e03199, at https://doi.org/10.1002/ecs2.3199. |
Multiple wildfires with minimal consequences—Low-severity wildfire effects on West Texas piñon-juniper woodlands | H. M. Poulos, C. M. Reemts, K. A. Wogan, J. P. Karges, R. G. Gatewood | 2020 | Poulos, H.M., Reemts, C.M., Wogan, K.A., Karges, J.P., and Gatewood, R.G., 2020, Multiple wildfires with minimal consequences—Low-severity wildfire effects on West Texas piñon-juniper woodlands: Forest Ecology and Management, v. 473, article 118293, at https://doi.org/10.1016/j.foreco.2020.118293. |
Mixed-severity wildfire as a driver of vegetation change in an Arizona Madrean Sky Island System, USA | H. M. Poulos, M. R. Freiburger, A. M. Barton, A. H. Taylor | 2021 | Poulos, H.M., Freiburger, M.R., Barton, A.M., and Taylor, A.H., 2021, Mixed-severity wildfire as a driver of vegetation change in an Arizona Madrean Sky Island System, USA: Fire, v. 4, no. 4, article 78, at https://doi.org/10.3390/fire4040078. |
Wildfire severity and vegetation recovery drive post?fire evapotranspiration in a southwestern pine?oak forest, Arizona, USA | H. M. Poulos, A. M. Barton, G. W. Koch, T. E. Kolb, A. E. Thode, M. Disney, S. Levick | 2021 | Poulos, H.M., Barton, A.M., Koch, G.W., Kolb, T.E., Thode, A.E., Disney, M., and Levick, S., 2021, Wildfire severity and vegetation recovery drive post?fire evapotranspiration in a southwestern pine?oak forest, Arizona, USA: Remote Sensing in Ecology and Conservation, v. 7, no. 4, p. 579–591, at https://doi.org/10.1002/rse2.210. |
Vegetation regrowth following wildfires in the Santa Cruz Mountains of northern California monitored using Landsat satellite image analysis | C. S. Potter | 2016 | Potter, C.S., 2016, Vegetation regrowth following wildfires in the Santa Cruz Mountains of northern California monitored using Landsat satellite image analysis: Open Journal of Forestry, v. 6, no. 2, p. 82–93, at https://doi.org/10.4236/ojf.2016.62008. |
Wildfire effects on permafrost and soil moisture in spruce forests of interior Alaska | C. Potter, C. Hugny | 2018 | Potter, C., and Hugny, C., 2018, Wildfire effects on permafrost and soil moisture in spruce forests of interior Alaska: Journal of Forestry Research, v. 31, no. 2, p. 553–563, at https://doi.org/10.1007/s11676-018-0831-2. |
Controls on land surface temperature in deserts of southern California derived from MODIS satellite time series analysis, 2000 to 2018 | C. Potter, D. Coppernoll-Houston | 2019 | Potter, C., and Coppernoll-Houston, D., 2019, Controls on land surface temperature in deserts of southern California derived from MODIS satellite time series analysis, 2000 to 2018: Climate, v. 7, no. 2, article 32, at https://doi.org/10.3390/cli7020032. |
Changes in vegetation phenology and productivity in Alaska over the past two decades | C. Potter, O. Alexander | 2020 | Potter, C., and Alexander, O., 2020, Changes in vegetation phenology and productivity in Alaska over the past two decades: Remote Sensing, v. 12, no. 10, article 1546, at https://doi.org/10.3390/rs12101546. |
Changes in vegetation cover and snowmelt timing in the Noatak National Preserve of northwestern Alaska estimated from MODIS and Landsat satellite image analysis | C. Potter, O. Alexander | 2019 | Potter, C., and Alexander, O., 2019, Changes in vegetation cover and snowmelt timing in the Noatak National Preserve of northwestern Alaska estimated from MODIS and Landsat satellite image analysis: European Journal of Remote Sensing, v. 52, no. 1, p. 542–556, at https://doi.org/10.1080/22797254.2019.1689852. |
Changes in vegetation cover of Yukon River drainages in interior Alaska—Estimated from MODIS greenness trends, 2000 to 2018 | C. Potter | 2020 | Potter, C., 2020, Changes in vegetation cover of Yukon River drainages in interior Alaska—Estimated from MODIS greenness trends, 2000 to 2018: Northwest Science, v. 94, no. 2, p. 160–175, at https://doi.org/10.3955/046.094.0206. |
Changes in growing season phenology following wildfires in Alaska | C. Potter | 2020 | Potter, C., 2020, Changes in growing season phenology following wildfires in Alaska: Remote Sensing in Earth Systems Sciences, v. 3, no. 1-2, p. 95–109, at https://doi.org/10.1007/s41976-020-00038-7. |
Shifts in vegetation cover of southern California deserts in response to recent climate variations | C. Potter | 2019 | Potter, C., 2019, Shifts in vegetation cover of southern California deserts in response to recent climate variations: Remote Sensing in Earth Systems Sciences, v. 2, p. 79–87, at https://doi.org/10.1007/s41976-019-00013-x. |
Changes in vegetation cover of Yellowstone National Park estimated from MODIS greenness trends, 2000 to 2018 | C. Potter | 2019 | Potter, C., 2019, Changes in vegetation cover of Yellowstone National Park estimated from MODIS greenness trends, 2000 to 2018: Remote Sensing in Earth Systems Sciences, v. 2, no. 2-3, p. 147–160, at https://doi.org/10.1007/s41976-019-00019-5. |
Changes in vegetation cover of the arctic national wildlife refuge estimated from MODIS greenness trends, 2000–18 | C. Potter | 2019 | Potter, C., 2019, Changes in vegetation cover of the arctic national wildlife refuge estimated from MODIS greenness trends, 2000–18: Earth Interactions, v. 23, article 4, at https://doi.org/10.1175/EI-D-18-0018.1. |
Recovery rates of Wetland Vegetation Greenness in severely burned ecosystems of Alaska derived from satellite image analysis | C. Potter | 2018 | Potter, C., 2018, Recovery rates of Wetland Vegetation Greenness in severely burned ecosystems of Alaska derived from satellite image analysis: Remote Sensing, v. 10, no. 9, article 1456, at https://doi.org/10.3390/rs10091456. |
Ecosystem carbon emissions from 2015 forest fires in interior Alaska | C. Potter | 2018 | Potter, C., 2018, Ecosystem carbon emissions from 2015 forest fires in interior Alaska: Carbon Balance and Management, v. 13, no. 1, article 2, at https://doi.org/10.1186/s13021-017-0090-0. |
Fire-climate history and landscape patterns of high burn severity areas on the California southern and central coast | C. Potter | 2017 | Potter, C., 2017, Fire-climate history and landscape patterns of high burn severity areas on the California southern and central coast: Journal of Coastal Conservation, v. 21, no. 3, p. 393–404, at https://doi.org/10.1007/s11852-017-0519-3. |
Vegetation cover change in Glacier National Park detected using 25 years of Landsat satellite image analysis | C. Potter | 2016 | Potter, C., 2016, Vegetation cover change in Glacier National Park detected using 25 years of Landsat satellite image analysis: Journal of Biodiversity Management & Forestry, v. 5, no. 1, p. 1–7, at https://doi.org/10.4172/2327-4417.1000156. |
Landscape patterns of vegetation canopy regrowth following wildfires in the Sierra Nevada Mountains of California | C. Potter | 2015 | Potter, C., 2015, Landscape patterns of vegetation canopy regrowth following wildfires in the Sierra Nevada Mountains of California: Open Journal of Forestry, v. 5, no. 7, p. 723–732, at https://doi.org/10.4236/ojf.2015.57064. |
Assessment of the immediate impacts of the 2013–2014 drought on ecosystems of the California central coast | C. Potter | 2015 | Potter, C., 2015, Assessment of the immediate impacts of the 2013–2014 drought on ecosystems of the California central coast: Western North American Naturalist, v. 75, no. 2, p. 129–145, at https://doi.org/10.3398/064.075.0202. |
Weather factors associated with extremely large fires and fire growth days | B. E. Potter, D. McEvoy | 2021 | Potter, B.E., and McEvoy, D., 2021, Weather factors associated with extremely large fires and fire growth days: Earth Interactions, v. 25, no. 1, p. 160–176, at https://doi.org/10.1175/ei-d-21-0008.1. |
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Estimating climate-sensitive wildfire risk and tree mortality models for use in broad-scale U.S. forest carbon projections | R. Pokharel, G. Latta, S. B. Ohrel | 2023 | Pokharel, R., Latta, G., and Ohrel, S.B., 2023, Estimating climate-sensitive wildfire risk and tree mortality models for use in broad-scale U.S. forest carbon projections: Forests, v. 14, no. 2, article 302, at https://doi.org/10.3390/f14020302. |
A protocol for collecting burned area time series cross-check data | H. R. Podschwit, B. Potter, N. K. Larkin | 2022 | Podschwit, H.R., Potter, B., and Larkin, N.K., 2022, A protocol for collecting burned area time series cross-check data: Fire, v. 5, no. 5, article 153, at https://doi.org/10.3390/fire5050153. |
Multi-model forecasts of very-large fire occurences during the end of the 21st century | H. R. Podschwit, N. K. Larkin, E. A. Steel, A. Cullen, E. Alvarado | 2018 | Podschwit, H.R., Larkin, N.K., Steel, E.A., Cullen, A., and Alvarado, E., 2018, Multi-model forecasts of very-large fire occurences during the end of the 21st century: Climate, v. 6, no. 4, article 100, at https://doi.org/10.3390/cli6040100. |
Estimating wildfire growth from noisy and incomplete incident data using a state space model | H. Podschwit, P. Guttorp, N. Larkin, E. A. Steel | 2018 | Podschwit, H., Guttorp, P., Larkin, N., and Steel, E.A., 2018, Estimating wildfire growth from noisy and incomplete incident data using a state space model: Environmental and Ecological Statistics, v. 25, no. 3, p. 325–340, at https://doi.org/10.1007/s10651-018-0407-5. |
Patterns and trends in simultaneous wildfire activity in the United States from 1984 to 2015 | H. Podschwit, A. Cullen | 2020 | Podschwit, H., and Cullen, A., 2020, Patterns and trends in simultaneous wildfire activity in the United States from 1984 to 2015: International Journal of Wildland Fire, v. 29, no. 12, p. 1057–1071, at https://doi.org/10.1071/Wf19150. |
Fire refugia are robust across western US forested ecoregions, 1986–2021 | R. V. Platt, T. B. Chapman, J. K. Balch | 2023 | Platt, R.V., Chapman, T.B., and Balch, J.K., 2023, Fire refugia are robust across western US forested ecoregions, 1986–2021: Environmental Research Letters, v. 19, no. 1, article 014044, at https://doi.org/10.1088/1748-9326/ad11bf. |
Priorities and effectiveness in wildfire management—Evidence from fire spread in the western United States | A. J. Plantinga, R. Walsh, M. Wibbenmeyer | 2022 | Plantinga, A.J., Walsh, R., and Wibbenmeyer, M., 2022, Priorities and effectiveness in wildfire management—Evidence from fire spread in the western United States: Journal of the Association of Environmental and Resource Economists, v. 9, no. 4, p. 603–639, at https://doi.org/10.1086/719426. |
A deep learning approach for mapping and dating burned areas using temporal sequences of satellite images | M. M. Pinto, R. Libonati, R. M. Trigo, I. F. Trigo, C. C. DaCamara | 2020 | Pinto, M.M., Libonati, R., Trigo, R.M., Trigo, I.F., and DaCamara, C.C., 2020, A deep learning approach for mapping and dating burned areas using temporal sequences of satellite images: ISPRS Journal of Photogrammetry and Remote Sensing, v. 160, p. 260–274, at https://doi.org/10.1016/j.isprsjprs.2019.12.014. |
Impactos de los incendios forestales de magnitud en áreas silvestres protegidas de Chile Central | J. F. Pinilla, M. C. Soto, R. M. N. Cerrillo | 2023 | Pinilla, J.F., Soto, M.C., and Cerrillo, R.M.N., 2023, Impactos de los incendios forestales de magnitud en áreas silvestres protegidas de Chile Central: Bosque, v. 44, no. 1, p. 83–95, at https://doi.org/10.4067/S0717-92002023000100083. |
The influence of fire history on soil nutrients and vegetation cover in mixed-severity fire regime forests of the eastern Olympic Peninsula, Washington, USA | M. R. A. Pingree, T. H. DeLuca | 2018 | Pingree, M.R.A., and DeLuca, T.H., 2018, The influence of fire history on soil nutrients and vegetation cover in mixed-severity fire regime forests of the eastern Olympic Peninsula, Washington, USA: Forest Ecology and Management, v. 422, p. 95–107, at https://doi.org/10.1016/j.foreco.2018.03.037. |
Adsorption capacity of wildfire-produced charcoal from Pacific Northwest forests | M. R. A. Pingree, E. E. DeLuca, D. T. Schwartz, T. H. DeLuca | 2016 | Pingree, M.R.A., DeLuca, E.E., Schwartz, D.T., and DeLuca, T.H., 2016, Adsorption capacity of wildfire-produced charcoal from Pacific Northwest forests: Geoderma, v. 283, p. 68–77, at https://doi.org/10.1016/j.geoderma.2016.07.016. |
Refining the cheatgrass-fire cycle in the Great Basin—Precipitation timing and fine fuel composition predict wildfire trends | D. S. Pilliod, J. L. Welty, R. S. Arkle | 2017 | Pilliod, D.S., Welty, J.L., and Arkle, R.S., 2017, Refining the cheatgrass-fire cycle in the Great Basin—Precipitation timing and fine fuel composition predict wildfire trends: Ecology and Evolution, v. 7, no. 19, p. 8126–8151, at https://doi.org/10.1002/ece3.3414. |
Consequential lightning-caused wildfires and the “let burn” narrative | B. M. Pietruszka, J. D. Young, K. C. Short, L. A. St. Denis, M. P. Thompson, D. E. Calkin | 2023 | Pietruszka, B.M., Young, J.D., Short, K.C., St. Denis, L.A., Thompson, M.P., and Calkin, D.E., 2023, Consequential lightning-caused wildfires and the “let burn” narrative: Fire Ecology, v. 19, no. 1, article 50, at https://doi.org/10.1186/s42408-023-00208-0. |
Use of random forests for modeling and mapping forest canopy fuels for fire behavior analysis in Lassen Volcanic National Park, California, USA | A. D. Pierce, C. A. Farris, A. H. Taylor | 2012 | Pierce, A.D., Farris, C.A., and Taylor, A.H., 2012, Use of random forests for modeling and mapping forest canopy fuels for fire behavior analysis in Lassen Volcanic National Park, California, USA: Forest Ecology and Management, v. 279, p. 77–89, at https://doi.org/10.1016/j.foreco.2012.05.010. |
1984–2010 trends in fire burn severity and area for the conterminous US | J. J. Picotte, B. Peterson, G. Meier, S. M. Howard | 2016 | Picotte, J.J., Peterson, B., Meier, G., and Howard, S.M., 2016, 1984–2010 trends in fire burn severity and area for the conterminous US: International Journal of Wildland Fire, v. 25, no. 4, p. 413–420, at https://doi.org/10.1071/Wf15039. |
LANDFIRE Remap prototype mapping effort—Developing a new framework for mapping vegetation classification, change, and structure | J. J. Picotte, D. Dockter, J. Long, B. Tolk, A. Davidson, B. Peterson | 2019 | Picotte, J.J., Dockter, D., Long, J., Tolk, B., Davidson, A., and Peterson, B., 2019, LANDFIRE Remap prototype mapping effort—Developing a new framework for mapping vegetation classification, change, and structure: Fire, v. 2, no. 2, article 35, at https://doi.org/10.3390/fire2020035. |
Determination of burn severity models ranging from regional to national scales for the conterminous United States | J. J. Picotte, C. A. Cansler, C. A. Kolden, J. A. Lutz, C. Key, N. C. Benson, K. M. Robertson | 2021 | Picotte, J.J., Cansler, C.A., Kolden, C.A., Lutz, J.A., Key, C., Benson, N.C., and Robertson, K.M., 2021, Determination of burn severity models ranging from regional to national scales for the conterminous United States: Remote Sensing of Environment, v. 263, article 112569, at https://doi.org/10.1016/j.rse.2021.112569. |
Changes to the Monitoring Trends in Burn Severity program mapping production procedures and data products | J. J. Picotte, K. Bhattarai, D. Howard, J. Lecker, J. Epting, B. Quayle, N. Benson, K. Nelson | 2020 | Picotte, J.J., Bhattarai, K., Howard, D., Lecker, J., Epting, J., Quayle, B., Benson, N., and Nelson, K., 2020, Changes to the Monitoring Trends in Burn Severity program mapping production procedures and data products: Fire Ecology, v. 16, no. 1, article 16, at https://doi.org/10.1186/s42408-020-00076-y. |
Digital mapping of vegetative great groups to inform management strategies | L. Phipps, T. K. Stringham | 2024 | Phipps, L., and Stringham, T.K., 2024, Digital mapping of vegetative great groups to inform management strategies: Rangeland Ecology & Management, v. 94, p. 7–19, at https://doi.org/10.1016/j.rama.2024.01.006. |
Association between wildfires and coccidioidomycosis incidence in California, 2000–2018—A synthetic control analysis | S. Phillips, I. Jones, G. Sondermyer-Cooksey, A. T. Yu, A. K. Heaney, B. Zhou, A. Bhattachan, A. K. Weaver, S. K. Campo, W. Mgbara, R. Wagner, J. Taylor, D. Lettenmaier, G. S. Okin, S. Jain, D. Vugia, J. V. Remais, J. R. Head | 2023 | Phillips, S., Jones, I., Sondermyer-Cooksey, G., Yu, A.T., Heaney, A.K., Zhou, B., Bhattachan, A., Weaver, A.K., Campo, S.K., et al., 2023, Association between wildfires and coccidioidomycosis incidence in California, 2000–2018—A synthetic control analysis: Environmental Epidemiology, v. 7, no. 4, article e254, at https://doi.org/10.1097/ee9.0000000000000254. |
Using Landsat-derived disturbance and recovery history and lidar to map forest biomass dynamics | D. Pflugmacher, W. B. Cohen, R. E. Kennedy, Z. Yang | 2014 | Pflugmacher, D., Cohen, W.B., Kennedy, R.E., and Yang, Z., 2014, Using Landsat-derived disturbance and recovery history and lidar to map forest biomass dynamics: Remote Sensing of Environment, v. 151, p. 124–137, at https://doi.org/10.1016/j.rse.2013.05.033. |
Evaluating and monitoring forest fuel treatments using remote sensing applications in Arizona, U.S.A. | R. E. Petrakis, M. L. Villarreal, Z. Wu, R. Hetzler, B. R. Middleton, L. M. Norman | 2018 | Petrakis, R.E., Villarreal, M.L., Wu, Z., Hetzler, R., Middleton, B.R., and Norman, L.M., 2018, Evaluating and monitoring forest fuel treatments using remote sensing applications in Arizona, U.S.A.: Forest Ecology and Management, v. 413, p. 48–61, at https://doi.org/10.1016/j.foreco.2018.01.036. |
Riparian vegetation response amid variable climate conditions across the Upper Gila River watershed—Informing Tribal restoration priorities | R. E. Petrakis, L. M. Norman, B. R. Middleton | 2023 | Petrakis, R.E., Norman, L.M., and Middleton, B.R., 2023, Riparian vegetation response amid variable climate conditions across the Upper Gila River watershed—Informing Tribal restoration priorities: Frontiers in Environmental Science, v. 11, article 1179328, at https://doi.org/10.3389/fenvs.2023.1179328. |
Vegetative response to water availability on the San Carlos Apache Reservation | R. Petrakis, Z. Wu, J. McVay, B. Middleton, D. Dye, J. Vogel | 2016 | Petrakis, R., Wu, Z., McVay, J., Middleton, B., Dye, D., and Vogel, J., 2016, Vegetative response to water availability on the San Carlos Apache Reservation: Forest Ecology and Management, v. 378, p. 14–23, at https://doi.org/10.1016/j.foreco.2016.07.012. |
Trends in fire danger and population exposure along the wildland-urban interface | G. C. L. Peterson, S. E. Prince, A. G. Rappold | 2021 | Peterson, G.C.L., Prince, S.E., and Rappold, A.G., 2021, Trends in fire danger and population exposure along the wildland-urban interface: Environmental Science & Technology, v. 55, no. 23, p. 16257–16265, at https://doi.org/10.1021/acs.est.1c03835. |
Predicting streamflow duration from crowd-sourced flow observations | D. A. Peterson, S. K. Kampf, K. C. Puntenney-Desmond, M. P. Fairchild, S. Zipper, J. C. Hammond, M. R. V. Ross, M. G. Sears | 2024 | Peterson, D.A., Kampf, S.K., Puntenney-Desmond, K.C., Fairchild, M.P., Zipper, S., Hammond, J.C., Ross, M.R.V., and Sears, M.G., 2024, Predicting streamflow duration from crowd-sourced flow observations: Water Resources Research, v. 60, no. 1, article e2023WR035093, at https://doi.org/10.1029/2023WR035093. |
Effects of gradient, distance, curvature and aspect on steep burned and unburned hillslope soil erosion and deposition | L. M. Perreault, E. M. Yager, R. Aalto | 2017 | Perreault, L.M., Yager, E.M., and Aalto, R., 2017, Effects of gradient, distance, curvature and aspect on steep burned and unburned hillslope soil erosion and deposition: Earth Surface Processes and Landforms, v. 42, no. 7, p. 1033–1048, at https://doi.org/10.1002/esp.4067. |
Application of 210Pbex inventories to measure net hillslope erosion at burned sites | L. M. Perreault, E. M. Yager, R. Aalto | 2013 | Perreault, L.M., Yager, E.M., and Aalto, R., 2013, Application of 210Pbex inventories to measure net hillslope erosion at burned sites: Earth Surface Processes and Landforms, v. 38, no. 2, p. 133–145, at https://doi.org/10.1002/esp.3266. |
Multi-stage soil-hydraulic recovery and limited ravel accumulations following the 2017 Nuns and Tubbs wildfires in northern California | J. P. Perkins, D. Carlos, C. Skye, C.-D. Corina, J. Stock, J. P. Prancevic, M. Elisabeth, J. Jay | 2022 | Perkins, J.P., Carlos, D., Skye, C., Corina, C.-D., Stock, J., Prancevic, J.P., Elisabeth, M., and Jay, J., 2022, Multi-stage soil-hydraulic recovery and limited ravel accumulations following the 2017 Nuns and Tubbs wildfires in northern California: Journal of Geophysical Research—Earth Surface, v. 127, no. 6, article e2022JF006591, at https://doi.org/10.1029/2022JF006591. |
Wildfires can increase regulated nitrate, arsenic, and disinfection byproduct violations and concentrations in public drinking water supplies | M. J. Pennino, S. G. Leibowitz, J. E. Compton, M. Beyene, S. D. LeDuc | 2022 | Pennino, M.J., Leibowitz, S.G., Compton, J.E., Beyene, M., and LeDuc, S.D., 2022, Wildfires can increase regulated nitrate, arsenic, and disinfection byproduct violations and concentrations in public drinking water supplies: Science of the Total Environment, v. 804, article 149890, at https://doi.org/10.1016/j.scitotenv.2021.149890. |
Density-dependent plant growth drives grazer stimulation of aboveground net primary production in Yellowstone grasslands | J. F. Penner, D. A. Frank | 2021 | Penner, J.F., and Frank, D.A., 2021, Density-dependent plant growth drives grazer stimulation of aboveground net primary production in Yellowstone grasslands: Oecologia, v. 196, no. 3, p. 851–861, at https://doi.org/10.1007/s00442-021-04960-5. |
Changes in climate and land cover affect seasonal streamflow forecasts in the Rio Grande headwaters | C. A. Penn, D. W. Clow, G. A. Sexstone, S. F. Murphy | 2020 | Penn, C.A., Clow, D.W., Sexstone, G.A., and Murphy, S.F., 2020, Changes in climate and land cover affect seasonal streamflow forecasts in the Rio Grande headwaters: Journal of the American Water Resources Association, v. 56, no. 5, p. 882–902, at https://doi.org/10.1111/1752-1688.12863. |
Quality control and assessment of interpreter consistency of annual land cover reference data in an operational national monitoring program | B. W. Pengra, S. V. Stehman, J. A. Horton, D. J. Dockter, T. A. Schroeder, Z. Yang, W. B. Cohen, S. P. Healey, T. R. Loveland | 2020 | Pengra, B.W., Stehman, S.V., Horton, J.A., Dockter, D.J., Schroeder, T.A., Yang, Z., Cohen, W.B., Healey, S.P., and Loveland, T.R., 2020, Quality control and assessment of interpreter consistency of annual land cover reference data in an operational national monitoring program: Remote Sensing of Environment, v. 238, article 111261, at https://doi.org/10.1016/j.rse.2019.111261. |
Using Landsat imagery to assess burn severity of national forest inventory plots | F. Pelletier, B. N. I. Eskelson, V. J. Monleon, Y. C. Tseng | 2021 | Pelletier, F., Eskelson, B.N.I., Monleon, V.J., and Tseng, Y.C., 2021, Using Landsat imagery to assess burn severity of national forest inventory plots: Remote Sensing, v. 13, no. 10, article 1935, at https://doi.org/10.3390/rs13101935. |
Exploring invasibility with species distribution modeling—How does fire promote cheatgrass (Bromus tectorum) invasion within lower montane forests? | J. L. Peeler, E. A. H. Smithwick | 2018 | Peeler, J.L., and Smithwick, E.A.H., 2018, Exploring invasibility with species distribution modeling—How does fire promote cheatgrass (Bromus tectorum) invasion within lower montane forests?: Diversity and Distributions, v. 24, no. 9, p. 1308–1320, at https://doi.org/10.1111/ddi.12765. |
Spatial dynamics of tree group and gap structure in an old-growth ponderosa pine-California black oak forest burned by repeated wildfires | N. C. Pawlikowski, M. Coppoletta, E. Knapp, A. H. Taylor | 2019 | Pawlikowski, N.C., Coppoletta, M., Knapp, E., and Taylor, A.H., 2019, Spatial dynamics of tree group and gap structure in an old-growth ponderosa pine-California black oak forest burned by repeated wildfires: Forest Ecology and Management, v. 434, p. 289–302, at https://doi.org/10.1016/j.foreco.2018.12.016. |
Understanding the effect of large wildfires on residents' well-being—What factors influence wildfire impact? | T. B. Paveglio, C. Kooistra, T. Hall, M. Pickering | 2016 | Paveglio, T.B., Kooistra, C., Hall, T., and Pickering, M., 2016, Understanding the effect of large wildfires on residents' well-being—What factors influence wildfire impact?: Forest Science, v. 62, no. 1, p. 59–69, at https://doi.org/10.5849/forsci.15-021. |
Persistent composition legacy and rapid structural change following successive fires in Sierra Nevada mixed conifer forests | A. Paudel, M. Coppoletta, K. Merriam, S. H. Markwith | 2022 | Paudel, A., Coppoletta, M., Merriam, K., and Markwith, S.H., 2022, Persistent composition legacy and rapid structural change following successive fires in Sierra Nevada mixed conifer forests: Forest Ecology and Management, v. 509, article 120079, at https://doi.org/10.1016/j.foreco.2022.120079. |
Rapid monitoring of the abundance and spread of exotic annual grasses in the western United States using remote sensing and machine learning | N. J. Pastick, B. K. Wylie, M. B. Rigge, D. Dahal, S. P. Boyte, M. O. Jones, B. W. Allred, S. Parajuli, Z. Wu | 2021 | Pastick, N.J., Wylie, B.K., Rigge, M.B., Dahal, D., Boyte, S.P., Jones, M.O., Allred, B.W., Parajuli, S., and Wu, Z., 2021, Rapid monitoring of the abundance and spread of exotic annual grasses in the western United States using remote sensing and machine learning: AGU Advances, v. 2, no. 2, article e2020AV000298, at https://doi.org/10.1029/2020av000298. |
Spatial variability and landscape controls of near-surface permafrost within the Alaskan Yukon River Basin | N. J. Pastick, M. T. Jorgenson, B. K. Wylie, J. R. Rose, M. Rigge, M. A. Walvoord | 2014 | Pastick, N.J., Jorgenson, M.T., Wylie, B.K., Rose, J.R., Rigge, M., and Walvoord, M.A., 2014, Spatial variability and landscape controls of near-surface permafrost within the Alaskan Yukon River Basin: Journal of Geophysical Research—Biogeosciences, v. 119, no. 6, article 2013JG002594, at https://doi.org/10.1002/2013JG002594. |
Extending airborne electromagnetic surveys for regional active layer and permafrost mapping with remote sensing and ancillary data, Yukon Flats ecoregion, central Alaska | N. J. Pastick, M. T. Jorgenson, B. K. Wylie, B. J. Minsley, L. Ji, M. A. Walvoord, B. D. Smith, J. D. Abraham, J. R. Rose | 2013 | Pastick, N.J., Jorgenson, M.T., Wylie, B.K., Minsley, B.J., Ji, L., Walvoord, M.A., Smith, B.D., Abraham, J.D., and Rose, J.R., 2013, Extending airborne electromagnetic surveys for regional active layer and permafrost mapping with remote sensing and ancillary data, Yukon Flats ecoregion, central Alaska: Permafrost and Periglacial Processes, v. 24, no. 3, p. 184–199, at https://doi.org/10.1002/ppp.1775. |
Spatiotemporal remote sensing of ecosystem change and causation across Alaska | N. J. Pastick, M. T. Jorgenson, S. J. Goetz, B. M. Jones, B. K. Wylie, B. J. Minsley, H. Genet, J. F. Knight, D. K. Swanson, J. C. Jorgenson | 2019 | Pastick, N.J., Jorgenson, M.T., Goetz, S.J., Jones, B.M., Wylie, B.K., Minsley, B.J., Genet, H., Knight, J.F., Swanson, D.K., and Jorgenson, J.C., 2019, Spatiotemporal remote sensing of ecosystem change and causation across Alaska: Global Change Biology, v. 25, no. 3, p. 1171–1189, at https://doi.org/10.1111/gcb.14279. |
Recovery of western black-legged tick and vertebrate populations after a destructive wildfire in an intensively-studied woodland in northern California | E. L. Pascoe, C. E. Vaughn, M. I. Jones, R. H. Barrett, J. E. Foley, R. S. Lane | 2023 | Pascoe, E.L., Vaughn, C.E., Jones, M.I., Barrett, R.H., Foley, J.E., and Lane, R.S., 2023, Recovery of western black-legged tick and vertebrate populations after a destructive wildfire in an intensively-studied woodland in northern California: Journal of Vector Ecology, v. 48, no. 1, p. 19–36, at https://doi.org/10.52707/1081-1710-48.1.19. |
Benefits of the fire mitigation ecosystem service in The Great Dismal Swamp National Wildlife Refuge, Virginia, USA | B. Parthum, E. Pindilli, D. Hogan | 2017 | Parthum, B., Pindilli, E., and Hogan, D., 2017, Benefits of the fire mitigation ecosystem service in The Great Dismal Swamp National Wildlife Refuge, Virginia, USA: Journal of Environmental Management, v. 203, p. 375–382, at https://doi.org/10.1016/j.jenvman.2017.08.018. |
Land transitions from multivariate time series—Using seasonal trend analysis and segmentation to detect land-cover changes | B. Parmentier, J. R. Eastman | 2014 | Parmentier, B., and Eastman, J.R., 2014, Land transitions from multivariate time series—Using seasonal trend analysis and segmentation to detect land-cover changes: International Journal of Remote Sensing, v. 35, no. 2, p. 671–692, at https://doi.org/10.1080/01431161.2013.871595. |
Characterization of land transitions patterns from multivariate time series using seasonal trend analysis and principal component analysis | B. Parmentier | 2014 | Parmentier, B., 2014, Characterization of land transitions patterns from multivariate time series using seasonal trend analysis and principal component analysis: Remote Sensing, v. 6, no. 12, p. 12639–12665, at https://doi.org/10.3390/rs61212639. |
Fine-scale spatial climate variation and drought mediate the likelihood of reburning | S. A. Parks, M. A. Parisien, C. Miller, L. M. Holsinger, L. S. Baggett | 2018 | Parks, S.A., Parisien, M.A., Miller, C., Holsinger, L.M., and Baggett, L.S., 2018, Fine-scale spatial climate variation and drought mediate the likelihood of reburning: Ecological Applications, v. 28, no. 2, p. 573–586, at https://doi.org/10.1002/eap.1671. |
Fire activity and severity in the western US vary along proxy gradients representing fuel amount and fuel moisture | S. A. Parks, M. A. Parisien, C. Miller, S. Z. Dobrowski | 2014 | Parks, S.A., Parisien, M.A., Miller, C., and Dobrowski, S.Z., 2014, Fire activity and severity in the western US vary along proxy gradients representing fuel amount and fuel moisture: PLoS ONE, v. 9, no. 6, article e99699, at https://doi.org/10.1371/journal.pone.0099699. |
Wildland fire deficit and surplus in the western United States, 1984–2012 | S. A. Parks, C. Miller, M.-A. Parisien, L. M. Holsinger, S. Z. Dobrowski, J. Abatzoglou | 2015 | Parks, S.A., Miller, C., Parisien, M.-A., Holsinger, L.M., Dobrowski, S.Z., and Abatzoglou, J., 2015, Wildland fire deficit and surplus in the western United States, 1984–2012: Ecosphere, v. 6, no. 12, article 275, at https://doi.org/10.1890/es15-00294.1. |
Previous fires moderate burn severity of subsequent wildland fires in two large western US wilderness areas | S. A. Parks, C. Miller, C. R. Nelson, Z. A. Holden | 2014 | Parks, S.A., Miller, C., Nelson, C.R., and Holden, Z.A., 2014, Previous fires moderate burn severity of subsequent wildland fires in two large western US wilderness areas: Ecosystems, v. 17, no. 1, p. 29–42, at https://doi.org/10.1007/s10021-013-9704-x. |
How will climate change affect wildland fire severity in the western US? | S. A. Parks, C. Miller, J. T. Abatzoglou, L. M. Holsinger, M.-A. Parisien, S. Z. Dobrowski | 2016 | Parks, S.A., Miller, C., Abatzoglou, J.T., Holsinger, L.M., Parisien, M.-A., and Dobrowski, S.Z., 2016, How will climate change affect wildland fire severity in the western US?: Environmental Research Letters, v. 11, no. 3, article 035002, at https://doi.org/10.1088/1748-9326/11/3/035002. |
Mean composite fire severity metrics computed with google earth engine offer improved accuracy and expanded mapping potential | S. A. Parks, L. M. Holsinger, M. A. Voss, R. A. Loehman, N. P. Robinson | 2018 | Parks, S.A., Holsinger, L.M., Voss, M.A., Loehman, R.A., and Robinson, N.P., 2018, Mean composite fire severity metrics computed with google earth engine offer improved accuracy and expanded mapping potential: Remote Sensing, v. 10, no. 6, article 879, at https://doi.org/10.3390/rs10060879. |
High-severity fire—Evaluating its key drivers and mapping its probability across western US forests | S. A. Parks, L. M. Holsinger, M. H. Panunto, W. M. Jolly, S. Z. Dobrowski, G. K. Dillon | 2018 | Parks, S.A., Holsinger, L.M., Panunto, M.H., Jolly, W.M., Dobrowski, S.Z., and Dillon, G.K., 2018, High-severity fire—Evaluating its key drivers and mapping its probability across western US forests: Environmental Research Letters, v. 13, no. 4, article 044037, at https://doi.org/10.1088/1748-9326/aab791. |
Wildland fire as a self-regulating mechanism—The role of previous burns and weather in limiting fire progression | S. A. Parks, L. M. Holsinger, C. Miller, C. R. Nelson | 2015 | Parks, S.A., Holsinger, L.M., Miller, C., and Nelson, C.R., 2015, Wildland fire as a self-regulating mechanism—The role of previous burns and weather in limiting fire progression: Ecological Applications, v. 25, no. 6, p. 1478–1492, at https://doi.org/10.1890/14-1430.1.sm. |
Contemporary wildfires are more severe compared to the historical reference period in western US dry conifer forests | S. A. Parks, L. M. Holsinger, K. Blankenship, G. K. Dillon, S. A. Goeking, R. Swaty | 2023 | Parks, S.A., Holsinger, L.M., Blankenship, K., Dillon, G.K., Goeking, S.A., and Swaty, R., 2023, Contemporary wildfires are more severe compared to the historical reference period in western US dry conifer forests: Forest Ecology and Management, v. 544, article 121232, at https://doi.org/10.1016/j.foreco.2023.121232. |
What drives low-severity fire in the southwestern USA? | S. A. Parks, S. Z. Dobrowski, M. H. Panunto | 2018 | Parks, S.A., Dobrowski, S.Z., and Panunto, M.H., 2018, What drives low-severity fire in the southwestern USA?: Forests, v. 9, no. 4, article 165, at https://doi.org/10.3390/f9040165. |
A new metric for quantifying burn severity—The relativized burn ratio | S. A. Parks, G. K. Dillon, C. Miller | 2014 | Parks, S.A., Dillon, G.K., and Miller, C., 2014, A new metric for quantifying burn severity—The relativized burn ratio: Remote Sensing, v. 6, no. 3, p. 1827–1844, at https://doi.org/10.3390/rs6031827. |
Warmer and drier fire seasons contribute to increases in area burned at high severity in western US forests from 1985 to 2017 | S. A. Parks, J. T. Abatzoglou | 2020 | Parks, S.A., and Abatzoglou, J.T., 2020, Warmer and drier fire seasons contribute to increases in area burned at high severity in western US forests from 1985 to 2017: Geophysical Research Letters, v. 47, no. 22, article e2020GL089858, at https://doi.org/10.1029/2020GL089858. |
Demographic effects of a megafire on a declining prairie grouse in the mixed-grass prairie | N. J. Parker, D. S. Sullins, D. A. Haukos, K. A. Fricke, C. A. Hagen, A. A. Ahlers | 2022 | Parker, N.J., Sullins, D.S., Haukos, D.A., Fricke, K.A., Hagen, C.A., and Ahlers, A.A., 2022, Demographic effects of a megafire on a declining prairie grouse in the mixed-grass prairie: Ecology and Evolution, v. 12, no. 12, article e9544, at https://doi.org/10.1002/ece3.9544. |
Recovery of working grasslands following a megafire in the southern mixed-grass prairie | N. J. Parker, D. S. Sullins, D. A. Haukos, K. A. Fricke, C. A. Hagen | 2022 | Parker, N.J., Sullins, D.S., Haukos, D.A., Fricke, K.A., and Hagen, C.A., 2022, Recovery of working grasslands following a megafire in the southern mixed-grass prairie: Global Ecology and Conservation, v. 36, article e02142, at https://doi.org/10.1016/j.gecco.2022.e02142. |
Characterizing spatial burn severity patterns of 2016 Chimney Tops 2 fire using multi-temporal Landsat and NEON LiDAR data | T. Park, S. Sim | 2023 | Park, T., and Sim, S., 2023, Characterizing spatial burn severity patterns of 2016 Chimney Tops 2 fire using multi-temporal Landsat and NEON LiDAR data: Frontiers in Remote Sensing, v. 4, article 1096000, at https://doi.org/10.3389/frsen.2023.1096000. |
Spatial variability in wildfire probability across the western United States | M. A. Parisien, S. Snetsinger, J. A. Greenberg, C. R. Nelson, T. Schoennagel, S. Z. Dobrowski, M. A. Moritz | 2012 | Parisien, M.A., Snetsinger, S., Greenberg, J.A., Nelson, C.R., Schoennagel, T., Dobrowski, S.Z., and Moritz, M.A., 2012, Spatial variability in wildfire probability across the western United States: International Journal of Wildland Fire, v. 21, no. 4, p. 313–327, at https://doi.org/10.1071/WF11044. |
The spatially varying influence of humans on fire probability in North America | M. A. Parisien, C. Miller, S. A. Parks, E. R. Delancey, F. N. Robinne, M. D. Flannigan | 2016 | Parisien, M.A., Miller, C., Parks, S.A., Delancey, E.R., Robinne, F.N., and Flannigan, M.D., 2016, The spatially varying influence of humans on fire probability in North America: Environmental Research Letters, v. 11, no. 7, article 075005, at https://doi.org/10.1088/1748-9326/11/7/075005. |
Abrupt, climate-induced increase in wildfires in British Columbia since the mid-2000s | M. A. Parisien, Q. E. Barber, M. L. Bourbonnais, L. D. Daniels, M. D. Flannigan, R. W. Gray, K. M. Hoffman, P. Jain, S. L. Stephens, S. W. Taylor, E. Whitman | 2023 | Parisien, M.A., Barber, Q.E., Bourbonnais, M.L., Daniels, L.D., Flannigan, M.D., Gray, R.W., Hoffman, K.M., Jain, P., Stephens, S.L., et al., 2023, Abrupt, climate-induced increase in wildfires in British Columbia since the mid-2000s: Communications Earth & Environment, v. 4, no. 1, article 309, at https://doi.org/10.1038/s43247-023-00977-1. |
Commentary on the article Burn probability simulation and subsequent wildland fire activity in Alberta, Canada - Implications for risk assessment and strategic planning by JL Beverly and N. McLoughlin | M. A. Parisien, A. A. Ager, A. M. Barros, D. Dawe, S. Erni, M. A. Finney, C. W. McHugh, C. Miller, S. A. Parks, K. L. Riley, K. C. Short, C. A. Stockdale, X. L. Wang, E. Whitman | 2020 | Parisien, M.A., Ager, A.A., Barros, A.M., Dawe, D., Erni, S., Finney, M.A., McHugh, C.W., Miller, C., Parks, S.A., et al., 2020, Commentary on the article Burn probability simulation and subsequent wildland fire activity in Alberta, Canada - Implications for risk assessment and strategic planning by JL Beverly and N. McLoughlin: Forest Ecology and Management, v. 460, article 117698, at https://doi.org/10.1016/j.foreco.2019.117698. |
Climate-altered fire regimes may increase extirpation risk in an upper subalpine conifer species of management concern | E. R. Pansing, D. F. Tomback, M. B. Wunder | 2020 | Pansing, E.R., Tomback, D.F., and Wunder, M.B., 2020, Climate-altered fire regimes may increase extirpation risk in an upper subalpine conifer species of management concern: Ecosphere, v. 11, no. 8, article e03220, at https://doi.org/10.1002/ecs2.3220. |
Differing sensitivities to fire disturbance result in large differences among remotely sensed products of vegetation disturbance | J. Palomino, M. Kelly | 2019 | Palomino, J., and Kelly, M., 2019, Differing sensitivities to fire disturbance result in large differences among remotely sensed products of vegetation disturbance: Ecosystems, v. 22, no. 8, p. 1767–1786, at https://doi.org/10.1007/s10021-019-00367-9. |
Turning up the heat—Long?term water quality responses to wildfires and climate change in a hypereutrophic lake | A. De Palma?Dow, I. M. McCullough, J. A. Brentrup | 2022 | De Palma?Dow, A., McCullough, I.M., and Brentrup, J.A., 2022, Turning up the heat—Long?term water quality responses to wildfires and climate change in a hypereutrophic lake: Ecosphere, v. 13, no. 12, article e4271, at https://doi.org/10.1002/ecs2.4271. |
Locating forest management units using remote sensing and geostatistical tools in north-central Washington, USA | P. Palaiologou, M. Essen, J. Hogland, K. Kalabokidis | 2020 | Palaiologou, P., Essen, M., Hogland, J., and Kalabokidis, K., 2020, Locating forest management units using remote sensing and geostatistical tools in north-central Washington, USA: Sensors, v. 20, no. 9, article 2454, at https://doi.org/10.3390/s20092454. |
A classification of US wildland firefighter entrapments based on coincident fuels, weather, and topography | W. G. Page, P. H. Freeborn, B. W. Butler, W. M. Jolly | 2019 | Page, W.G., Freeborn, P.H., Butler, B.W., and Jolly, W.M., 2019, A classification of US wildland firefighter entrapments based on coincident fuels, weather, and topography: Fire, v. 2, no. 4, article 52, at https://doi.org/10.3390/fire2040052. |
Spatial patterns of ponderosa pine regeneration in high-severity burn patches | S. M. Owen, C. H. Sieg, A. J. Sánchez Meador, P. Z. Fulé, J. M. Iniguez, L. S. Baggett, P. J. Fornwalt, M. A. Battaglia | 2017 | Owen, S.M., Sieg, C.H., Sánchez Meador, A.J., Fulé, P.Z., Iniguez, J.M., Baggett, L.S., Fornwalt, P.J., and Battaglia, M.A., 2017, Spatial patterns of ponderosa pine regeneration in high-severity burn patches: Forest Ecology and Management, v. 405, p. 134–149, at https://doi.org/10.1016/j.foreco.2017.09.005. |
Persistent effects of fire severity on ponderosa pine regeneration niches and seedling growth | S. M. Owen, C. H. Sieg, P. Z. Fulé, C. A. Gehring, L. Baggett, J. M. Iniguez, P. J. Fornwalt, M. A. Battaglia | 2020 | Owen, S.M., Sieg, C.H., Fulé, P.Z., Gehring, C.A., Baggett, L., Iniguez, J.M., Fornwalt, P.J., and Battaglia, M.A., 2020, Persistent effects of fire severity on ponderosa pine regeneration niches and seedling growth: Forest Ecology and Management, v. 477, article 118502, at https://doi.org/10.1016/j.foreco.2020.118502. |
Large, high-severity burn patches limit fungal recovery 13 years after wildfire in a ponderosa pine forest | S. M. Owen, A. M. Patterson, C. A. Gehring, C. H. Sieg, L. S. Baggett, P. Z. Fulé | 2019 | Owen, S.M., Patterson, A.M., Gehring, C.A., Sieg, C.H., Baggett, L.S., and Fulé, P.Z., 2019, Large, high-severity burn patches limit fungal recovery 13 years after wildfire in a ponderosa pine forest: Soil Biology and Biochemistry, v. 139, article 107616, at https://doi.org/10.1016/j.soilbio.2019.107616. |
Post-fire ponderosa pine regeneration with and without planting in Arizona and New Mexico | J. Ouzts, T. Kolb, D. Huffman, A. S. Meador | 2015 | Ouzts, J., Kolb, T., Huffman, D., and Meador, A.S., 2015, Post-fire ponderosa pine regeneration with and without planting in Arizona and New Mexico: Forest Ecology and Management, v. 354, p. 281–290, at https://doi.org/10.1016/j.foreco.2015.06.001. |
Effects of compound disturbance on Canada lynx and snowshoe hare—Wildfire and forest management influence timing and intensity of use | L. E. Olson, J. S. Crotteau, S. Fox, G. Hanvey, J. D. Holbrook, S. Jackson, J. R. Squires | 2023 | Olson, L.E., Crotteau, J.S., Fox, S., Hanvey, G., Holbrook, J.D., Jackson, S., and Squires, J.R., 2023, Effects of compound disturbance on Canada lynx and snowshoe hare—Wildfire and forest management influence timing and intensity of use: Forest Ecology and Management, v. 530, article 120757, at https://doi.org/10.1016/j.foreco.2022.120757. |
Projected climate-fire interactions drive forest to shrubland transition on an Arizona Sky Island | C. D. O’Connor, D. A. Falk, G. M. Garfin | 2020 | O’Connor, C.D., Falk, D.A., and Garfin, G.M., 2020, Projected climate-fire interactions drive forest to shrubland transition on an Arizona Sky Island: Frontiers in Environmental Science, v. 8, article 137, at https://doi.org/10.3389/fenvs.2020.00137. |
Getting ahead of the wildfire problem—Quantifying and mapping management challenges and opportunities | C. O’Connor, M. Thompson, F. Rodríguez y Silva | 2016 | O’Connor, C., Thompson, M., and Rodríguez y Silva, F., 2016, Getting ahead of the wildfire problem—Quantifying and mapping management challenges and opportunities: Geosciences, v. 6, no. 3, article 35, at https://doi.org/10.3390/geosciences6030035. |
Post-fire forest dynamics and climate variability affect spatial and temporal properties of spruce beetle outbreaks on a Sky Island mountain range | C. D. O'Connor, A. M. Lynch, D. A. Falk, T. W. Swetnam | 2015 | O'Connor, C.D., Lynch, A.M., Falk, D.A., and Swetnam, T.W., 2015, Post-fire forest dynamics and climate variability affect spatial and temporal properties of spruce beetle outbreaks on a Sky Island mountain range: Forest Ecology and Management, v. 336, p. 148–162, at https://doi.org/10.1016/j.foreco.2014.10.021. |
Fire severity, size, and climate associations diverge from historical precedent along an ecological gradient in the Pinaleño Mountains, Arizona, USA | C. D. O'Connor, D. A. Falk, A. M. Lynch, T. W. Swetnam | 2014 | O'Connor, C.D., Falk, D.A., Lynch, A.M., and Swetnam, T.W., 2014, Fire severity, size, and climate associations diverge from historical precedent along an ecological gradient in the Pinaleño Mountains, Arizona, USA: Forest Ecology and Management, v. 329, p. 264–278, at https://doi.org/10.1016/j.foreco.2014.06.032. |
An empirical machine learning method for predicting potential fire control locations for pre-fire planning and operational fire management | C. D. O'Connor, D. E. Calkin, M. P. Thompson | 2017 | O'Connor, C.D., Calkin, D.E., and Thompson, M.P., 2017, An empirical machine learning method for predicting potential fire control locations for pre-fire planning and operational fire management: International Journal of Wildland Fire, v. 26, no. 7, p. 587–597, at https://doi.org/10.1071/wf16135. |
Using social media data and machine learning to map recreational ecosystem services | C. Nyelele, C. Keske, M. G. Chung, H. Guo, B. N. Egoh | 2023 | Nyelele, C., Keske, C., Chung, M.G., Guo, H., and Egoh, B.N., 2023, Using social media data and machine learning to map recreational ecosystem services: Ecological Indicators, v. 154, article 110606, at https://doi.org/10.1016/j.ecolind.2023.110606. |
A new picture of fire extent, variability, and drought interaction in prescribed fire landscapes—Insights from Florida government records | H. K. Nowell, C. D. Holmes, K. Robertson, C. Teske, J. K. Hiers | 2018 | Nowell, H.K., Holmes, C.D., Robertson, K., Teske, C., and Hiers, J.K., 2018, A new picture of fire extent, variability, and drought interaction in prescribed fire landscapes—Insights from Florida government records: Geophysical Research Letters, v. 45, no. 15, p. 7874–7884, at https://doi.org/10.1029/2018GL078679. |
The impacts of rising vapour pressure deficit in natural and managed ecosystems | K. A. Novick, D. L. Ficklin, C. Grossiord, A. G. Konings, J. Martinez-Vilalta, W. Sadok, A. T. Trugman, A. P. Williams, A. J. Wright, J. T. Abatzoglou, M. P. Dannenberg, P. Gentine, K. Guan, M. R. Johnston, L. E. L. Lowman, D. J. P. Moore, N. G. McDowell | in press | Novick, K.A., Ficklin, D.L., Grossiord, C., Konings, A.G., Martinez-Vilalta, J., Sadok, W., Trugman, A.T., Williams, A.P., Wright, A.J., et al., in press, The impacts of rising vapour pressure deficit in natural and managed ecosystems: Plant, Cell & Environment, at https://doi.org/10.1111/pce.14846. |
Pyrosilviculture needed for landscape resilience of dry Western United States forests | M. P. North, R. A. York, B. M. Collins, M. D. Hurteau, G. M. Jones, E. E. Knapp, L. Kobziar, H. McCann, M. D. Meyer, S. L. Stephens, R. E. Tompkins, C. L. Tubbesing | 2021 | North, M.P., York, R.A., Collins, B.M., Hurteau, M.D., Jones, G.M., Knapp, E.E., Kobziar, L., McCann, H., Meyer, M.D., et al., 2021, Pyrosilviculture needed for landscape resilience of dry Western United States forests: Journal of Forestry, v. 119, no. 5, p. 520–544, at https://doi.org/10.1093/jofore/fvab026. |
Review of broad-scale drought monitoring of forests—Toward an integrated data mining approach | S. P. Norman, F. H. Koch, W. W. Hargrove | 2016 | Norman, S.P., Koch, F.H., and Hargrove, W.W., 2016, Review of broad-scale drought monitoring of forests—Toward an integrated data mining approach: Forest Ecology and Management, v. 380, p. 346–358, at https://doi.org/10.1016/j.foreco.2016.06.027. |
Wildfire catalyzes upward range expansion of trembling aspen in southern Rocky Mountain beetle-killed forests | K. M. Nigro, M. E. Rocca, M. A. Battaglia, J. D. Coop, M. D. Redmond | 2022 | Nigro, K.M., Rocca, M.E., Battaglia, M.A., Coop, J.D., and Redmond, M.D., 2022, Wildfire catalyzes upward range expansion of trembling aspen in southern Rocky Mountain beetle-killed forests: Journal of Biogeography, v. 49, no. 1, p. 201–214, at https://doi.org/10.1111/jbi.14302. |
Fire frequency impacts soil properties and processes in sagebrush steppe ecosystems of the Columbia Basin | L. Nichols, D. J. Shinneman, S. K. McIlroy, M.-A. de Graaff | 2021 | Nichols, L., Shinneman, D.J., McIlroy, S.K., and de Graaff, M.-A., 2021, Fire frequency impacts soil properties and processes in sagebrush steppe ecosystems of the Columbia Basin: Applied Soil Ecology, v. 165, article 103967, at https://doi.org/10.1016/j.apsoil.2021.103967. |
Topographic variation in tree group and gap structure in Sierra Nevada mixed-conifer forests with active fire regimes | J. Ng, M. P. North, A. J. Arditti, M. R. Cooper, J. A. Lutz | 2020 | Ng, J., North, M.P., Arditti, A.J., Cooper, M.R., and Lutz, J.A., 2020, Topographic variation in tree group and gap structure in Sierra Nevada mixed-conifer forests with active fire regimes: Forest Ecology and Management, v. 472, article 118220, at https://doi.org/10.1016/j.foreco.2020.118220. |
Prolonged drought in a northern California coastal region suppresses wildfire impacts on hydrology | M. E. Newcomer, J. Underwood, S. F. Murphy, C. Ulrich, T. Schram, S. R. Maples, J. Peña, E. R. Siirila?Woodburn, M. Trotta, J. Jasperse, D. Seymour, S. S. Hubbard | 2023 | Newcomer, M.E., Underwood, J., Murphy, S.F., Ulrich, C., Schram, T., Maples, S.R., Peña, J., Siirila?Woodburn, E.R., Trotta, M., et al., 2023, Prolonged drought in a northern California coastal region suppresses wildfire impacts on hydrology: Water Resources Research, v. 59, no. 8, article e2022WR034206, at https://doi.org/10.1029/2022wr034206. |
Influences of wildfire, habitat size, and connectivity on trout in headwater streams revealed by patterns of genetic diversity | H. Neville, J. Dunham, A. Rosenberger, J. Umek, B. Nelson | 2009 | Neville, H., Dunham, J., Rosenberger, A., Umek, J., and Nelson, B., 2009, Influences of wildfire, habitat size, and connectivity on trout in headwater streams revealed by patterns of genetic diversity: Transactions of the American Fisheries Society, v. 138, no. 6, p. 1314–1327, at https://doi.org/10.1577/T08-162.1. |
Do repeated wildfires promote restoration of oak woodlands in mixed-conifer landscapes? | D. G. Nemens, J. M. Varner, K. R. Kidd, B. Wing | 2018 | Nemens, D.G., Varner, J.M., Kidd, K.R., and Wing, B., 2018, Do repeated wildfires promote restoration of oak woodlands in mixed-conifer landscapes?: Forest Ecology and Management, v. 427, p. 143–151, at https://doi.org/10.1016/j.foreco.2018.05.023. |
Assessing spatiotemporal relationships between wildfire and mountain pine beetle disturbances across multiple time lags | M. F. Nelson, M. Ciochina, C. Bone | 2016 | Nelson, M.F., Ciochina, M., and Bone, C., 2016, Assessing spatiotemporal relationships between wildfire and mountain pine beetle disturbances across multiple time lags: Ecosphere, v. 7, no. 10, article e01482, at https://doi.org/10.1002/ecs2.1482. |
Landscape variation in tree regeneration and snag fall drive fuel loads in 24-year old post-fire lodgepole pine forests | K. N. Nelson, M. G. Turner, W. H. Romme, D. B. Tinker | 2016 | Nelson, K.N., Turner, M.G., Romme, W.H., and Tinker, D.B., 2016, Landscape variation in tree regeneration and snag fall drive fuel loads in 24-year old post-fire lodgepole pine forests: Ecological Applications, v. 26, no. 8, p. 2422–2436, at https://doi.org/10.1002/eap.1412. |
The LANDFIRE refresh strategy—Updating the national dataset | K. J. Nelson, J. Connot, B. Peterson, C. Martin | 2013 | Nelson, K.J., Connot, J., Peterson, B., and Martin, C., 2013, The LANDFIRE refresh strategy—Updating the national dataset: Fire Ecology, v. 9, no. 2, p. 80–101, at https://doi.org/10.4996/fireecology.0902080. |
Evaluating an automated approach for monitoring forest disturbances in the Pacific Northwest from logging, fire and insect outbreaks with Landsat time series data | C. S. R. Neigh, D. K. Bolton, J. J. Williams, M. Diabate | 2014 | Neigh, C.S.R., Bolton, D.K., Williams, J.J., and Diabate, M., 2014, Evaluating an automated approach for monitoring forest disturbances in the Pacific Northwest from logging, fire and insect outbreaks with Landsat time series data: Forests, v. 5, no. 12, p. 3169–3198, at https://doi.org/10.3390/f5123169. |
An automated approach to map the history of forest disturbance from insect mortality and harvest with Landsat time-series data | C. S. R. Neigh, D. K. Bolton, M. Diabate, J. J. Williams, N. Carvalhais | 2014 | Neigh, C.S.R., Bolton, D.K., Diabate, M., Williams, J.J., and Carvalhais, N., 2014, An automated approach to map the history of forest disturbance from insect mortality and harvest with Landsat time-series data: Remote Sensing, v. 6, no. 4, p. 2782–2808, at https://doi.org/10.3390/rs6042782. |
Influences of forest roads and their edge effects on the spatial pattern of burn severity | G. Narayanaraj, M. C. Wimberly | 2013 | Narayanaraj, G., and Wimberly, M.C., 2013, Influences of forest roads and their edge effects on the spatial pattern of burn severity: International Journal of Applied Earth Observation and Geoinformation, v. 23, p. 62–70, at https://doi.org/10.1016/j.jag.2012.12.006. |
Influences of forest roads on the spatial patterns of human- and lightning-caused wildfire ignitions | G. Narayanaraj, M. C. Wimberly | 2012 | Narayanaraj, G., and Wimberly, M.C., 2012, Influences of forest roads on the spatial patterns of human- and lightning-caused wildfire ignitions: Applied Geography, v. 32, no. 2, p. 878–888, at https://doi.org/10.1016/j.apgeog.2011.09.004. |
A synthesis of the effects of cheatgrass invasion on US Great Basin carbon storage | R. C. Nagy, E. J. Fusco, J. K. Balch, J. T. Finn, A. Mahood, J. M. Allen, B. A. Bradley | 2020 | Nagy, R.C., Fusco, E.J., Balch, J.K., Finn, J.T., Mahood, A., Allen, J.M., and Bradley, B.A., 2020, A synthesis of the effects of cheatgrass invasion on US Great Basin carbon storage: Journal of Applied Ecology, v. 58, no. 2, p. 327–337, at https://doi.org/10.1111/1365-2664.13770. |
Wilderness in the 21st century—A framework for testing assumptions about ecological intervention in wilderness using a case study of fire ecology in the Rocky Mountains | C. E. Naficy, E. G. Keeling, P. Landres, P. F. Hessburg, T. T. Veblen, A. Sala | 2016 | Naficy, C.E., Keeling, E.G., Landres, P., Hessburg, P.F., Veblen, T.T., and Sala, A., 2016, Wilderness in the 21st century—A framework for testing assumptions about ecological intervention in wilderness using a case study of fire ecology in the Rocky Mountains: Journal of Forestry, v. 114, no. 3, p. 384–395, at https://doi.org/10.5849/jof.15-010. |
Forest fire severity affects host plant quality and insect herbivore damage | S. M. Murphy, M. C. Vidal, T. P. Smith, C. J. Hallagan, E. D. Broder, D. Rowland, L. C. Cepero | 2018 | Murphy, S.M., Vidal, M.C., Smith, T.P., Hallagan, C.J., Broder, E.D., Rowland, D., and Cepero, L.C., 2018, Forest fire severity affects host plant quality and insect herbivore damage: Frontiers in Ecology and Evolution, v. 6, article 135, at https://doi.org/10.3389/fevo.2018.00135. |
Beyond the 1984 perspective—Narrow focus on modern wildfire trends underestimates future risks to water security | B. P. Murphy, L. L. Yocom, P. Belmont | 2018 | Murphy, B.P., Yocom, L.L., and Belmont, P., 2018, Beyond the 1984 perspective—Narrow focus on modern wildfire trends underestimates future risks to water security: Earth's Future, v. 6, no. 11, p. 1492–1497, at https://doi.org/10.1029/2018ef001006. |
Post-wildfire sediment cascades—A modeling framework linking debris flow generation and network-scale sediment routing | B. P. Murphy, J. A. Czuba, P. Belmont | 2019 | Murphy, B.P., Czuba, J.A., and Belmont, P., 2019, Post-wildfire sediment cascades—A modeling framework linking debris flow generation and network-scale sediment routing: Earth Surface Processes and Landforms, v. 44, no. 11, p. 2126–2140, at https://doi.org/10.1002/esp.4635. |
Define–Investigate–Estimate–Map (Diem) framework for modeling habitat threats | K. Muhammed, A. Anandhi, G. Chen, K. Poole | 2021 | Muhammed, K., Anandhi, A., Chen, G., and Poole, K., 2021, Define–Investigate–Estimate–Map (Diem) framework for modeling habitat threats: Sustainability, v. 13, no. 20, article 11259, at https://doi.org/10.3390/su132011259. |
Climate relationships with increasing wildfire in the southwestern US from 1984 to 2015 | S. E. Mueller, A. E. Thode, E. Q. Margolis, L. L. Yocom, J. D. Young, J. M. Iniguez | 2020 | Mueller, S.E., Thode, A.E., Margolis, E.Q., Yocom, L.L., Young, J.D., and Iniguez, J.M., 2020, Climate relationships with increasing wildfire in the southwestern US from 1984 to 2015: Forest Ecology and Management, v. 460, article 117861, at https://doi.org/10.1016/j.foreco.2019.117861. |
Satellite-based assessment of climate controls on US burned area | D. C. Morton, G. J. Collatz, D. Wang, J. T. Randerson, L. Giglio, Y. Chen | 2013 | Morton, D.C., Collatz, G.J., Wang, D., Randerson, J.T., Giglio, L., and Chen, Y., 2013, Satellite-based assessment of climate controls on US burned area: Biogeosciences, v. 10, no. 1, p. 247–260, at https://doi.org/10.5194/bg-10-247-2013. |
Post-wildfire salvage logging effects on snag structure and dead woody fuel loadings | C. J. Morris, M. C. Kennedy, S. C. Harrison, E. Alvarado, C. Desautel, J. Holford, S. Logue | 2023 | Morris, C.J., Kennedy, M.C., Harrison, S.C., Alvarado, E., Desautel, C., Holford, J., and Logue, S., 2023, Post-wildfire salvage logging effects on snag structure and dead woody fuel loadings: Canadian Journal of Forest Research, v. 53, no. 2, p. 103–118, at https://doi.org/10.1139/cjfr-2021-0089. |
Using a trait-based approach to asses fire resistance in forest landscapes of the Inland Northwest, USA | J. V. Moris, M. J. Reilly, Z. Yang, W. B. Cohen, R. Motta, D. Ascoli | 2022 | Moris, J.V., Reilly, M.J., Yang, Z., Cohen, W.B., Motta, R., and Ascoli, D., 2022, Using a trait-based approach to asses fire resistance in forest landscapes of the Inland Northwest, USA: Landscape Ecology, v. 37, p. 2149–2164, at https://doi.org/10.1007/s10980-022-01478-w. |
Mapping tree cover expansion in Montana, U.S.A. rangelands using high-resolution historical aerial imagery | S. L. Morford, B. W. Allred, E. R. Jensen, J. D. Maestas, K. R. Mueller, C. L. Pacholski, J. T. Smith, J. D. Tack, K. N. Tackett, D. E. Naugle | 2024 | Morford, S.L., Allred, B.W., Jensen, E.R., Maestas, J.D., Mueller, K.R., Pacholski, C.L., Smith, J.T., Tack, J.D., Tackett, K.N., and Naugle, D.E., 2024, Mapping tree cover expansion in Montana, U.S.A. rangelands using high-resolution historical aerial imagery: Remote Sensing in Ecology and Conservation, v. 10, no. 1, p. 91–105, at https://doi.org/10.1002/rse2.357. |
A comparison of burned area time series in the Alaskan boreal forests from different remote sensing products | R. Moreno, L. García, Arbelo | 2019 | Moreno, R., García, L., and Arbelo, 2019, A comparison of burned area time series in the Alaskan boreal forests from different remote sensing products: Forests, v. 10, no. 5, article 363, at https://doi.org/10.3390/f10050363. |
Mapping forest canopy fuels in the western United States with LiDAR-Landsat covariance | C. J. Moran, V. R. Kane, C. A. Seielstad | 2020 | Moran, C.J., Kane, V.R., and Seielstad, C.A., 2020, Mapping forest canopy fuels in the western United States with LiDAR-Landsat covariance: Remote Sensing, v. 12, no. 6, article 1000, at https://doi.org/10.3390/rs12061000. |
Creosote growth rate and reproduction increase in postfire environments | R. Lee Molinari, T. B. B. Bishop, M. F. Bekker, S. G. Kitchen, L. Allphin, S. B. St Clair | 2019 | Lee Molinari, R., Bishop, T.B.B., Bekker, M.F., Kitchen, S.G., Allphin, L., and St Clair, S.B., 2019, Creosote growth rate and reproduction increase in postfire environments: Ecology and Evolution, v. 9, no. 22, p. 12897–12905, at https://doi.org/10.1002/ece3.5771. |
Relative importance of abiotic, biotic, and disturbance drivers of plant community structure in the sagebrush steppe | R. M. Mitchell, J. D. Bakker, J. B. Vincent, G. M. Davies | 2017 | Mitchell, R.M., Bakker, J.D., Vincent, J.B., and Davies, G.M., 2017, Relative importance of abiotic, biotic, and disturbance drivers of plant community structure in the sagebrush steppe: Ecological Applications, v. 27, no. 3, p. 756–768, at https://doi.org/10.1002/eap.1479. |
Using geographic information to analyze wildland firefighter situational awareness—Impacts of spatial resolution on visibility assessment | K. A. Mistick, P. E. Dennison, M. J. Campbell, M. P. Thompson | 2022 | Mistick, K.A., Dennison, P.E., Campbell, M.J., and Thompson, M.P., 2022, Using geographic information to analyze wildland firefighter situational awareness—Impacts of spatial resolution on visibility assessment: Fire, v. 5, no. 5, article 151, at https://doi.org/10.3390/fire5050151. |
Fire severity and regeneration strategy influence shrub patch size and structure following disturbance | J. Minor, D. A. Falk, G. A. Barron-Gafford | 2017 | Minor, J., Falk, D.A., and Barron-Gafford, G.A., 2017, Fire severity and regeneration strategy influence shrub patch size and structure following disturbance: Forests, v. 8, no. 7, article 221, at https://doi.org/10.3390/f8070221. |
Rapid-response tools and datasets for post-fire remediation—Linking remote sensing and process-based hydrological models | M. E. Miller, W. J. Elliot, M. Billmire, P. R. Robichaud, K. A. Endsley | 2016 | Miller, M.E., Elliot, W.J., Billmire, M., Robichaud, P.R., and Endsley, K.A., 2016, Rapid-response tools and datasets for post-fire remediation—Linking remote sensing and process-based hydrological models: International Journal of Wildland Fire, v. 25, no. 10, p. 1061–1073, at https://doi.org/10.1071/wf15162. |
Socio-economic impact of the Rapid Response Erosion Database (RRED) | M. E. Miller, W. S. Breffle, M. Battaglia, D. Banach, P. R. Robichaud, W. J. Elliot, R. McClusky, I. S. Miller, M. Billmire | 2022 | Miller, M.E., Breffle, W.S., Battaglia, M., Banach, D., Robichaud, P.R., Elliot, W.J., McClusky, R., Miller, I.S., and Billmire, M., 2022, Socio-economic impact of the Rapid Response Erosion Database (RRED): Journal of Geoscience and Environment Protection, v. 10, no. 10, p. 103–125, at https://doi.org/10.4236/gep.2022.1010009. |
Trends and causes of severity, size, and number of fires in northwestern California, USA | J. D. Miller, C. N. Skinner, H. D. Safford, E. E. Knapp, C. M. Ramirez | 2012 | Miller, J.D., Skinner, C.N., Safford, H.D., Knapp, E.E., and Ramirez, C.M., 2012, Trends and causes of severity, size, and number of fires in northwestern California, USA: Ecological Applications, v. 22, no. 1, p. 184–203, at https://doi.org/10.1890/10-2108.1. |
Using one year post-fire fire severity assessments to estimate longer-term effects of fire in conifer forests of northern and eastern California, USA | J. D. Miller, H. D. Safford, K. R. Welch | 2016 | Miller, J.D., Safford, H.D., and Welch, K.R., 2016, Using one year post-fire fire severity assessments to estimate longer-term effects of fire in conifer forests of northern and eastern California, USA: Forest Ecology and Management, v. 382, p. 168–183, at https://doi.org/10.1016/j.foreco.2016.10.017. |
Trends in wildfire severity—1984 to 2010 in the Sierra Nevada, Modoc Plateau, and southern Cascades, California, USA | J. D. Miller, H. Safford | 2012 | Miller, J.D., and Safford, H., 2012, Trends in wildfire severity—1984 to 2010 in the Sierra Nevada, Modoc Plateau, and southern Cascades, California, USA: Fire Ecology, v. 8, no. 3, p. 41–57, at https://doi.org/10.4996/fireecology.0803041. |
Calibration and validation of immediate post-fire satellite-derived data to three severity metrics | J. D. Miller, B. Quayle | 2015 | Miller, J.D., and Quayle, B., 2015, Calibration and validation of immediate post-fire satellite-derived data to three severity metrics: Fire Ecology, v. 11, no. 2, p. 12–30, at https://doi.org/10.4996/fireecology.1102012. |
Differences in wildfires among ecoregions and land management agencies in the Sierra Nevada region, California, USA | J. D. Miller, B. M. Collins, J. A. Lutz, S. L. Stephens, J. W. van Wagtendonk, D. A. Yasuda | 2012 | Miller, J.D., Collins, B.M., Lutz, J.A., Stephens, S.L., van Wagtendonk, J.W., and Yasuda, D.A., 2012, Differences in wildfires among ecoregions and land management agencies in the Sierra Nevada region, California, USA: Ecosphere, v. 3, no. 9, p. 1–20, at https://doi.org/10.1890/ES12-00158.1. |
Different approaches make comparing studies of burn severity challenging—A review of methods used to link remotely sensed data with the Composite Burn Index | C. W. Miller, B. J. Harvey, V. R. Kane, L. M. Moskal, E. Alvarado | 2023 | Miller, C.W., Harvey, B.J., Kane, V.R., Moskal, L.M., and Alvarado, E., 2023, Different approaches make comparing studies of burn severity challenging—A review of methods used to link remotely sensed data with the Composite Burn Index: International Journal of Wildland Fire, v. 32, no. 4, p. 449–475, at https://doi.org/10.1071/wf22050. |
Progress in wilderness fire science—Embracing complexity | C. Miller, G. H. Aplet | 2016 | Miller, C., and Aplet, G.H., 2016, Progress in wilderness fire science—Embracing complexity: Journal of Forestry, v. 114, no. 3, p. 373–383, at https://doi.org/10.5849/jof.15-008. |
Logistic regression versus XGBoost for detecting burned areas using satellite images | A. F. Militino, H. Goyena, U. Pérez-Goya, M. D. Ugarte | 2024 | Militino, A.F., Goyena, H., Pérez-Goya, U., and Ugarte, M.D., 2024, Logistic regression versus XGBoost for detecting burned areas using satellite images: Environmental and Ecological Statistics, v. 31, p. 57–77, at https://doi.org/10.1007/s10651-023-00590-7. |
Relative importance of climate and mountain pine beetle outbreaks on the occurrence of large wildfires in the western USA | N. Mietkiewicz, D. Kulakowski | 2016 | Mietkiewicz, N., and Kulakowski, D., 2016, Relative importance of climate and mountain pine beetle outbreaks on the occurrence of large wildfires in the western USA: Ecological Applications, v. 26, no. 8, p. 2523–2535, at https://doi.org/10.1002/eap.1400. |
In the line of fire—Consequences of human-ignited wildfires to homes in the U.S. (1992–2015) | N. Mietkiewicz, J. K. Balch, T. Schoennagel, S. Leyk, L. A. St. Denis, B. A. Bradley | 2020 | Mietkiewicz, N., Balch, J.K., Schoennagel, T., Leyk, S., St. Denis, L.A., and Bradley, B.A., 2020, In the line of fire—Consequences of human-ignited wildfires to homes in the U.S. (1992–2015): Fire, v. 3, no. 3, article 50, at https://doi.org/10.3390/fire3030050. |
Quantifying changes in total and pyrogenic carbon stocks across fire severity gradients using active wildfire incidents | J. Miesel, A. Reiner, C. Ewell, B. Maestrini, M. Dickinson | 2018 | Miesel, J., Reiner, A., Ewell, C., Maestrini, B., and Dickinson, M., 2018, Quantifying changes in total and pyrogenic carbon stocks across fire severity gradients using active wildfire incidents: Frontiers in Earth Science, v. 6, article 41, at https://doi.org/10.3389/feart.2018.00041. |
Patterns of canopy and surface layer consumption in a boreal forest fire from repeat airborne lidar | A. Michael, C. M. Douglas, D. C. Bruce, A. Hans-Erik, B. Chad, P. Robert | 2017 | Michael, A., Douglas, C.M., Bruce, D.C., Hans-Erik, A., Chad, B., and Robert, P., 2017, Patterns of canopy and surface layer consumption in a boreal forest fire from repeat airborne lidar: Environmental Research Letters, v. 12, no. 6, article 065004, at https://doi.org/10.1088/1748-9326/aa6ade. |
The global lake area, climate, and population dataset—A new tool for addressing critical limnological questions | M. F. Meyer, M. R. Brousil, A. N. Cramer, B. P. Lanouette, J. C. Padowski, S. E. Hampton | 2020 | Meyer, M.F., Brousil, M.R., Cramer, A.N., Lanouette, B.P., Padowski, J.C., and Hampton, S.E., 2020, The global lake area, climate, and population dataset—A new tool for addressing critical limnological questions: Limnology and Oceanography Bulletin, v. 29, no. 4, p. 110–116, at https://doi.org/10.1002/lob.10406. |
Forest fire severity patterns of resource objective wildfires in the southern Sierra Nevada | M. D. Meyer | 2015 | Meyer, M.D., 2015, Forest fire severity patterns of resource objective wildfires in the southern Sierra Nevada: Journal of Forestry, v. 113, no. 1, p. 49–56, at https://doi.org/10.5849/jof.14-084. |
Circuit theory to estimate natal dispersal routes and functional landscape connectivity for an endangered small mammal | M. J. Merrick, J. L. Koprowski | 2017 | Merrick, M.J., and Koprowski, J.L., 2017, Circuit theory to estimate natal dispersal routes and functional landscape connectivity for an endangered small mammal: Landscape Ecology, v. 32, no. 6, p. 1163–1179, at https://doi.org/10.1007/s10980-017-0521-z. |
Non-equilibrium in plant distribution models—Only an issue for introduced or dispersal limited species? | D. R. Menuz, K. M. Kettenring, C. P. Hawkins, D. R. Cutler | 2015 | Menuz, D.R., Kettenring, K.M., Hawkins, C.P., and Cutler, D.R., 2015, Non-equilibrium in plant distribution models—Only an issue for introduced or dispersal limited species?: Ecography, v. 38, no. 3, p. 231–240, at https://doi.org/10.1111/ecog.00928. |
The importance of roads, nutrients, and climate for invasive plant establishment in riparian areas in the northwestern United States | D. R. Menuz, K. M. Kettenring | 2013 | Menuz, D.R., and Kettenring, K.M., 2013, The importance of roads, nutrients, and climate for invasive plant establishment in riparian areas in the northwestern United States: Biological Invasions, v. 15, no. 7, p. 1601–1612, at https://doi.org/10.1007/s10530-012-0395-6. |
Snow-cover remote sensing of conifer tree recovery in high-severity burn patches | C. Menick, W. Tinkham, C. Hoffman, M. Vanderhoof, J. Vogeler | 2024 | Menick, C., Tinkham, W., Hoffman, C., Vanderhoof, M., and Vogeler, J., 2024, Snow-cover remote sensing of conifer tree recovery in high-severity burn patches: Remote Sensing of Environment, v. 305, article 114114, at https://doi.org/10.1016/j.rse.2024.114114. |
Using high spatial resolution satellite imagery to map forest burn severity across spatial scales in a Pine Barrens ecosystem | R. Meng, J. Wu, K. L. Schwager, F. Zhao, P. E. Dennison, B. D. Cook, K. Brewster, T. M. Green, S. P. Serbin | 2017 | Meng, R., Wu, J., Schwager, K.L., Zhao, F., Dennison, P.E., Cook, B.D., Brewster, K., Green, T.M., and Serbin, S.P., 2017, Using high spatial resolution satellite imagery to map forest burn severity across spatial scales in a Pine Barrens ecosystem: Remote Sensing of Environment, v. 191, p. 95–109, at https://doi.org/10.1016/j.rse.2017.01.016. |
Landsat-based monitoring of southern pine beetle infestation severity and severity change in a temperate mixed forest | R. Meng, R. Gao, F. Zhao, C. Huang, R. Sun, Z. Lv, Z. Huang | 2022 | Meng, R., Gao, R., Zhao, F., Huang, C., Sun, R., Lv, Z., and Huang, Z., 2022, Landsat-based monitoring of southern pine beetle infestation severity and severity change in a temperate mixed forest: Remote Sensing of Environment, v. 269, article 112847, at https://doi.org/10.1016/j.rse.2021.112847. |
Effects of fire severity and post-fire climate on short-term vegetation recovery of mixed-conifer and red fir forests in the Sierra Nevada Mountains of California | R. Meng, P. E. Dennison, C. Huang, M. A. Moritz, C. D'Antonio | 2015 | Meng, R., Dennison, P.E., Huang, C., Moritz, M.A., and D'Antonio, C., 2015, Effects of fire severity and post-fire climate on short-term vegetation recovery of mixed-conifer and red fir forests in the Sierra Nevada Mountains of California: Remote Sensing of Environment, v. 171, p. 311–325, at https://doi.org/10.1016/j.rse.2015.10.024. |
Remote sensing analysis of vegetation recovery following short-interval fires in southern California shrublands | R. Meng, P. E. Dennison, C. M. D'Antonio, M. A. Moritz | 2014 | Meng, R., Dennison, P.E., D'Antonio, C.M., and Moritz, M.A., 2014, Remote sensing analysis of vegetation recovery following short-interval fires in southern California shrublands: PLoS ONE, v. 9, no. 10, article e110637, at https://doi.org/10.1371/journal.pone.0110637. |
Landscape-scale simulation of heterogeneous fire effects on pyrogenic carbon emissions, tree mortality, and net ecosystem production | G. W. Meigs, D. P. Turner, W. D. Ritts, Z. Yang, B. E. Law | 2011 | Meigs, G.W., Turner, D.P., Ritts, W.D., Yang, Z., and Law, B.E., 2011, Landscape-scale simulation of heterogeneous fire effects on pyrogenic carbon emissions, tree mortality, and net ecosystem production: Ecosystems, v. 14, no. 5, p. 758–775, at https://doi.org/10.1007/s10021-011-9444-8. |
Composition and structure of forest fire refugia—What are the ecosystem legacies across burned landscapes? | G. W. Meigs, M. A. Krawchuk | 2018 | Meigs, G.W., and Krawchuk, M.A., 2018, Composition and structure of forest fire refugia—What are the ecosystem legacies across burned landscapes?: Forests, v. 9, no. 5, article 243, at https://doi.org/10.3390/f9050243. |
Spatiotemporal dynamics of recent mountain pine beetle and western spruce budworm outbreaks across the Pacific Northwest Region, USA | G. W. Meigs, R. E. Kennedy, A. N. Gray, M. J. Gregory | 2015 | Meigs, G.W., Kennedy, R.E., Gray, A.N., and Gregory, M.J., 2015, Spatiotemporal dynamics of recent mountain pine beetle and western spruce budworm outbreaks across the Pacific Northwest Region, USA: Forest Ecology and Management, v. 339, p. 71–86, at https://doi.org/10.1016/j.foreco.2014.11.030. |
A Landsat time series approach to characterize bark beetle and defoliator impacts on tree mortality and surface fuels in conifer forests | G. W. Meigs, R. E. Kennedy, W. B. Cohen | 2011 | Meigs, G.W., Kennedy, R.E., and Cohen, W.B., 2011, A Landsat time series approach to characterize bark beetle and defoliator impacts on tree mortality and surface fuels in conifer forests: Remote Sensing of Environment, v. 115, no. 12, p. 3707–3718, at https://doi.org/10.1016/j.rse.2011.09.009. |
Influence of topography and fuels on fire refugia probability under varying fire weather conditions in forests of the Pacific Northwest, USA | G. W. Meigs, C. J. Dunn, S. A. Parks, M. A. Krawchuk | 2020 | Meigs, G.W., Dunn, C.J., Parks, S.A., and Krawchuk, M.A., 2020, Influence of topography and fuels on fire refugia probability under varying fire weather conditions in forests of the Pacific Northwest, USA: Canadian Journal of Forest Research, v. 50, no. 7, p. 636–647, at https://doi.org/10.1139/cjfr-2019-0406. |
Drought, wildfire and forest transformation—Characterizing trailing edge forests in the eastern Cascade Range, Washington, USA | G. W. Meigs, M. J. Case, D. J. Churchill, C. M. Hersey, S. M. A. Jeronimo, L. A. C. Smith, D. Thom | 2023 | Meigs, G.W., Case, M.J., Churchill, D.J., Hersey, C.M., Jeronimo, S.M.A., Smith, L.A.C., and Thom, D., 2023, Drought, wildfire and forest transformation—Characterizing trailing edge forests in the eastern Cascade Range, Washington, USA: Forestry—An International Journal of Forest Research, v. 96, no. 3, p. 340–354, at https://doi.org/10.1093/forestry/cpac046. |
Does wildfire likelihood increase following insect outbreaks in conifer forests? | G. W. Meigs, J. L. Campbell, H. S. J. Zald, J. D. Bailey, D. C. Shaw, R. E. Kennedy | 2015 | Meigs, G.W., Campbell, J.L., Zald, H.S.J., Bailey, J.D., Shaw, D.C., and Kennedy, R.E., 2015, Does wildfire likelihood increase following insect outbreaks in conifer forests?: Ecosphere, v. 6, no. 7, article 118, at https://doi.org/10.1890/ES15-00037.1. |
Spatiotemporal patterns of unburned areas within fire perimeters in the northwestern United States from 1984 to 2014 | A. J. H. Meddens, C. A. Kolden, J. A. Lutz, J. T. Abatzoglou, A. T. Hudak | 2018 | Meddens, A.J.H., Kolden, C.A., Lutz, J.A., Abatzoglou, J.T., and Hudak, A.T., 2018, Spatiotemporal patterns of unburned areas within fire perimeters in the northwestern United States from 1984 to 2014: Ecosphere, v. 9, no. 2, article e02029, at https://doi.org/10.1002/ecs2.2029. |
Detecting unburned areas within wildfire perimeters using Landsat and ancillary data across the northwestern United States | A. J. H. Meddens, C. A. Kolden, J. A. Lutz | 2016 | Meddens, A.J.H., Kolden, C.A., and Lutz, J.A., 2016, Detecting unburned areas within wildfire perimeters using Landsat and ancillary data across the northwestern United States: Remote Sensing of Environment, v. 186, p. 275–285, at https://doi.org/10.1016/j.rse.2016.08.023. |
Modelling species distributions and environmental suitability highlights risk of plant invasions in western United States | D. E. McMahon, A. K. Urza, J. L. Brown, C. Phelan, J. C. Chambers | 2021 | McMahon, D.E., Urza, A.K., Brown, J.L., Phelan, C., and Chambers, J.C., 2021, Modelling species distributions and environmental suitability highlights risk of plant invasions in western United States: Diversity and Distributions, v. 27, no. 4, p. 710–728, at https://doi.org/10.1111/ddi.13232. |
Food webs for three burn severities after wildfire in the Eldorado National Forest, California | J. P. McLaughlin, J. W. Schroeder, A. M. White, K. Culhane, H. E. Mirts, G. L. Tarbill, L. Sire, M. Page, E. J. Baker, M. Moritz, J. Brashares, H. S. Young, R. Sollmann | 2022 | McLaughlin, J.P., Schroeder, J.W., White, A.M., Culhane, K., Mirts, H.E., Tarbill, G.L., Sire, L., Page, M., Baker, E.J., et al., 2022, Food webs for three burn severities after wildfire in the Eldorado National Forest, California: Scientific Data, v. 9, no. 1, article 384, at https://doi.org/10.1038/s41597-022-01220-w. |
Fire as a fundamental ecological process—Research advances and frontiers | K. K. McLauchlan, P. E. Higuera, J. Miesel, B. M. Rogers, J. Schweitzer, J. K. Shuman, A. J. Tepley, J. M. Varner, T. T. Veblen, S. A. Adalsteinsson, J. K. Balch, P. Baker, E. Batllori, E. Bigio, P. Brando, M. Cattau, M. L. Chipman, J. Coen, R. Crandall, L. Daniels, N. Enright, W. S. Gross, B. J. Harvey, J. A. Hatten, S. Hermann, R. E. Hewitt, L. N. Kobziar, J. B. Landesmann, M. M. Loranty, S. Y. Maezumi, L. Mearns, M. Moritz, J. A. Myers, J. G. Pausas, A. F. A. Pellegrini, W. J. Platt, J. Roozeboom, H. Safford, F. Santos, R. M. Scheller, R. L. Sherriff, K. G. Smith, M. D. Smith, A. C. Watts | 2020 | McLauchlan, K.K., Higuera, P.E., Miesel, J., Rogers, B.M., Schweitzer, J., Shuman, J.K., Tepley, A.J., Varner, J.M., Veblen, T.T., et al., 2020, Fire as a fundamental ecological process—Research advances and frontiers: Journal of Ecology, v. 108, no. 5, p. 2047–2069, at https://doi.org/10.1111/1365-2745.13403. |
Systematic review and meta-analysis of fire regime research in ponderosa pine (Pinus ponderosa) ecosystems, Colorado, USA | S. T. McKinney | 2019 | McKinney, S.T., 2019, Systematic review and meta-analysis of fire regime research in ponderosa pine (Pinus ponderosa) ecosystems, Colorado, USA: Fire Ecology, v. 15, no. 1, article 38, at https://doi.org/10.1186/s42408-019-0056-6. |
Post-fire aspen (Populus tremuloides) regeneration varies in response to winter precipitation across a regional climate gradient | S. K. McIlroy, D. J. Shinneman | 2020 | McIlroy, S.K., and Shinneman, D.J., 2020, Post-fire aspen (Populus tremuloides) regeneration varies in response to winter precipitation across a regional climate gradient: Forest Ecology and Management, v. 455, article 117681, at https://doi.org/10.1016/j.foreco.2019.117681. |
Pyrogeography of the western Great Plains—A 40-year history of fire in semi-arid rangelands | D. A. McGranahan, C. L. Wonkka | 2024 | McGranahan, D.A., and Wonkka, C.L., 2024, Pyrogeography of the western Great Plains—A 40-year history of fire in semi-arid rangelands: Fire, v. 7, no. 1, article 32, at https://doi.org/10.3390/fire7010032. |
Fuel properties of effective greenstrips in simulated cheatgrass fires | D. A. McGranahan, C. L. Wonkka | 2022 | McGranahan, D.A., and Wonkka, C.L., 2022, Fuel properties of effective greenstrips in simulated cheatgrass fires: Environmental Management, v. 70, p. 319–328, at https://doi.org/10.1007/s00267-022-01659-y. |
Future regional increases in simultaneous large western USA wildfires | S. McGinnis, L. Kessenich, L. Mearns, A. Cullen, H. Podschwit, M. Bukovsky | 2023 | McGinnis, S., Kessenich, L., Mearns, L., Cullen, A., Podschwit, H., and Bukovsky, M., 2023, Future regional increases in simultaneous large western USA wildfires: International Journal of Wildland Fire, v. 32, no. 9, p. 1304–1314, at https://doi.org/10.1071/WF22107. |
Establishing relationships between drought indices and wildfire danger outputs—A test case for the California-Nevada Drought Early Warning System | D. McEvoy, M. Hobbins, T. Brown, K. VanderMolen, T. Wall, J. Huntington, M. Svoboda | 2019 | McEvoy, D., Hobbins, M., Brown, T., VanderMolen, K., Wall, T., Huntington, J., and Svoboda, M., 2019, Establishing relationships between drought indices and wildfire danger outputs—A test case for the California-Nevada Drought Early Warning System: Climate, v. 7, no. 4, article 52, at https://doi.org/10.3390/cli7040052. |
Hazards of risk—Identifying plausible community wildfire disasters in low-frequency fire regimes | A. McEvoy, B. K. Kerns, J. B. Kim | 2021 | McEvoy, A., Kerns, B.K., and Kim, J.B., 2021, Hazards of risk—Identifying plausible community wildfire disasters in low-frequency fire regimes: Forests, v. 12, no. 7, article 934, at https://doi.org/10.3390/f12070934. |
Effects of forest disturbance on water yield and peak flow in low?relief glaciated catchments assessed with Bayesian parameter estimation | Z. P. McEachran, G. C. Reese, D. L. Karwan, R. A. Slesak, J. Vogeler | 2023 | McEachran, Z.P., Reese, G.C., Karwan, D.L., Slesak, R.A., and Vogeler, J., 2023, Effects of forest disturbance on water yield and peak flow in low?relief glaciated catchments assessed with Bayesian parameter estimation: Hydrological Processes, v. 37, no. 8, article e14956, at https://doi.org/10.1002/hyp.14956. |
Do lakes feel the burn? Ecological consequences of increasing exposure of lakes to fire in the continental United States | I. M. McCullough, K. S. Cheruvelil, J. F. Lapierre, N. R. Lottig, M. A. Moritz, J. Stachelek, P. A. Soranno | 2019 | McCullough, I.M., Cheruvelil, K.S., Lapierre, J.F., Lottig, N.R., Moritz, M.A., Stachelek, J., and Soranno, P.A., 2019, Do lakes feel the burn? Ecological consequences of increasing exposure of lakes to fire in the continental United States: Global Change Biology, v. 25, no. 9, p. 2841–2854, at https://doi.org/10.1111/gcb.14732. |
Fire characteristics and hydrologic connectivity influence short?term responses of north temperate lakes to wildfire | I. M. McCullough, J. A. Brentrup, T. Wagner, J. F. Lapierre, J. Henneck, A. M. Paul, M. Belair, M. A. Moritz, C. T. Filstrup | 2023 | McCullough, I.M., Brentrup, J.A., Wagner, T., Lapierre, J.F., Henneck, J., Paul, A.M., Belair, M., Moritz, M.A., and Filstrup, C.T., 2023, Fire characteristics and hydrologic connectivity influence short?term responses of north temperate lakes to wildfire: Geophysical Research Letters, v. 50, no. 16, article e2023GL103953, at https://doi.org/10.1029/2023gl103953. |
Wildfire and infant health—A geospatial approach to estimating the health impacts of wildfire smoke exposure | S. J. McCoy, X. Zhao | 2020 | McCoy, S.J., and Zhao, X., 2020, Wildfire and infant health—A geospatial approach to estimating the health impacts of wildfire smoke exposure: Applied Economics Letters, v. 28, no. 1, p. 32–37, at https://doi.org/10.1080/13504851.2020.1730747. |
Wildfire risk, salience & housing demand | S. J. McCoy, R. P. Walsh | 2018 | McCoy, S.J., and Walsh, R.P., 2018, Wildfire risk, salience & housing demand: Journal of Environmental Economics and Management, v. 91, p. 203–228, at https://doi.org/10.1016/j.jeem.2018.07.005. |
Evaluating the Mid-Infrared Bi-spectral Index for improved assessment of low-severity fire effects in a conifer forest | T. R. McCarley, A. M. S. Smith, C. A. Kolden, J. Kreitler | 2018 | McCarley, T.R., Smith, A.M.S., Kolden, C.A., and Kreitler, J., 2018, Evaluating the Mid-Infrared Bi-spectral Index for improved assessment of low-severity fire effects in a conifer forest: International Journal of Wildland Fire, v. 27, no. 6, p. 407–412, at https://doi.org/10.1071/Wf17137. |
Landscape-scale quantification of fire-induced change in canopy cover following mountain pine beetle outbreak and timber harvest | T. R. McCarley, C. A. Kolden, N. M. Vaillant, A. T. Hudak, A. M. S. Smith, J. Kreitler | 2017 | McCarley, T.R., Kolden, C.A., Vaillant, N.M., Hudak, A.T., Smith, A.M.S., and Kreitler, J., 2017, Landscape-scale quantification of fire-induced change in canopy cover following mountain pine beetle outbreak and timber harvest: Forest Ecology and Management, v. 391, p. 164–175, at https://doi.org/10.1016/j.foreco.2017.02.015. |
Predicting fine-scale forage distribution to inform ungulate nutrition | T. R. McCarley, T. M. Ball, J. L. Aycrigg, E. K. Strand, L. K. Svancara, J. S. Horne, T. N. Johnson, M. K. Lonneker, M. Hurley | 2020 | McCarley, T.R., Ball, T.M., Aycrigg, J.L., Strand, E.K., Svancara, L.K., Horne, J.S., Johnson, T.N., Lonneker, M.K., and Hurley, M., 2020, Predicting fine-scale forage distribution to inform ungulate nutrition: Ecological Informatics, v. 60, article 101170, at https://doi.org/10.1016/j.ecoinf.2020.101170. |
Wildfire and topography impacts on snow accumulation and retention in montane forests | J. D. Maxwell, A. Call, S. B. St. Clair | 2019 | Maxwell, J.D., Call, A., and St. Clair, S.B., 2019, Wildfire and topography impacts on snow accumulation and retention in montane forests: Forest Ecology and Management, v. 432, p. 256–263, at https://doi.org/10.1016/j.foreco.2018.09.021. |
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Assessing the effectiveness of landscape-scale forest adaptation actions to improve resilience under projected climate change | C. J. Maxwell, R. M. Scheller, K. N. Wilson, P. N. Manley | 2022 | Maxwell, C.J., Scheller, R.M., Wilson, K.N., and Manley, P.N., 2022, Assessing the effectiveness of landscape-scale forest adaptation actions to improve resilience under projected climate change: Frontiers in Forests and Global Change, v. 5, article 740869, at https://doi.org/10.3389/ffgc.2022.740869. |
Identifying habitat holdouts for high elevation tree species under climate change | C. J. Maxwell, R. M. Scheller | 2020 | Maxwell, C.J., and Scheller, R.M., 2020, Identifying habitat holdouts for high elevation tree species under climate change: Frontiers in Forests and Global Change, v. 2, article 94, at https://doi.org/10.3389/ffgc.2019.00094. |
Comparison of model-assisted endogenous poststratification methods for estimation of above-ground biomass change in Oregon, USA | F. Mauro, V. J. Monleon, A. N. Gray, O. Kuegler, H. Temesgen, A. T. Hudak, P. A. Fekety, Z. Yang | 2022 | Mauro, F., Monleon, V.J., Gray, A.N., Kuegler, O., Temesgen, H., Hudak, A.T., Fekety, P.A., and Yang, Z., 2022, Comparison of model-assisted endogenous poststratification methods for estimation of above-ground biomass change in Oregon, USA: Remote Sensing, v. 14, no. 23, article 6024, at https://doi.org/10.3390/rs14236024. |
Arceuthobium microcarpum (Viscaceae)—Morphological evidence for continued species recognition and discrimination from Arceuthobium campylopodum | R. L. Mathiasen, S. C. Kenaley, J. M. Scott | 2018 | Mathiasen, R.L., Kenaley, S.C., and Scott, J.M., 2018, Arceuthobium microcarpum (Viscaceae)—Morphological evidence for continued species recognition and discrimination from Arceuthobium campylopodum: Phytologia, v. 100, no. 1, p. 71–90, at https://www.phytologia.org/uploads/2/3/4/2/23422706/100_1_71-90mathiasen.comments.revised_mathisaen3-18-18.pdf. |
Natural areas as a basis for assessing ecosystem vulnerability to climate change | M. H. Massie, T. M. Wilson, A. T. Morzillo, E. B. Henderson | 2016 | H. Massie, M., Wilson, T.M., Morzillo, A.T., and Henderson, E.B., 2016, Natural areas as a basis for assessing ecosystem vulnerability to climate change: Ecosphere, v. 7, no. 11, article e01563, at https://doi.org/10.1002/ecs2.1563. |
Interpretable machine learning for analysing heterogeneous drivers of geographic events in space-time | A. Masrur, M. Yu, P. Mitra, D. Peuquet, A. Taylor | 2021 | Masrur, A., Yu, M., Mitra, P., Peuquet, D., and Taylor, A., 2021, Interpretable machine learning for analysing heterogeneous drivers of geographic events in space-time: International Journal of Geographical Information Science, v. 36, no. 4, p. 692–719, at https://doi.org/10.1080/13658816.2021.1965608. |
Topography, climate and fire history regulate wildfire activity in the Alaskan tundra | A. Masrur, A. Taylor, L. Harris, J. Barnes, A. Petrov | 2022 | Masrur, A., Taylor, A., Harris, L., Barnes, J., and Petrov, A., 2022, Topography, climate and fire history regulate wildfire activity in the Alaskan tundra: Journal of Geophysical Research—Biogeosciences, v. 127, no. 3, article e2021JG006608, at https://doi.org/10.1029/2021JG006608. |
Effects of climate oscillations on wildland fire potential in the continental United States | S. A. Mason, P. E. Hamlington, B. D. Hamlington, W. M. Jolly, C. M. Hoffman | 2017 | Mason, S.A., Hamlington, P.E., Hamlington, B.D., Jolly, W.M., and Hoffman, C.M., 2017, Effects of climate oscillations on wildland fire potential in the continental United States: Geophysical Research Letters, v. 44, no. 13, p. 7002–7010, at https://doi.org/10.1002/2017gl074111. |
Spatial scale in prescribed fire regimes—An understudied aspect in conservation with examples from the southeastern United States | D. S. Mason, M. A. Lashley | 2021 | Mason, D.S., and Lashley, M.A., 2021, Spatial scale in prescribed fire regimes—An understudied aspect in conservation with examples from the southeastern United States: Fire Ecology, v. 17, no. 1, article 3, at https://doi.org/10.1186/s42408-020-00087-9. |
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Natural climate solutions provide robust carbon mitigation capacity under future climate change scenarios | D. C. Marvin, B. M. Sleeter, D. R. Cameron, E. Nelson, A. J. Plantinga | 2023 | Marvin, D.C., Sleeter, B.M., Cameron, D.R., Nelson, E., and Plantinga, A.J., 2023, Natural climate solutions provide robust carbon mitigation capacity under future climate change scenarios: Scientific Reports, v. 13, no. 1, article 19008, at https://doi.org/10.1038/s41598-023-43118-6. |
Characterizing persistent unburned islands within the Inland Northwest USA | A. J. Martinez, A. J. H. Meddens, C. A. Kolden, E. K. Strand, A. T. Hudak | 2019 | Martinez, A.J., Meddens, A.J.H., Kolden, C.A., Strand, E.K., and Hudak, A.T., 2019, Characterizing persistent unburned islands within the Inland Northwest USA: Fire Ecology, v. 15, no. 1, article 20, at https://doi.org/10.1186/s42408-019-0036-x. |
Regional-scale management maps for forested areas of the southeastern United States and the US Pacific Northwest | M. Marsik, C. G. Staub, W. J. Kleindl, J. M. Hall, C. S. Fu, D. Yang, F. R. Stevens, M. W. Binford | 2018 | Marsik, M., Staub, C.G., Kleindl, W.J., Hall, J.M., Fu, C.S., Yang, D., Stevens, F.R., and Binford, M.W., 2018, Regional-scale management maps for forested areas of the southeastern United States and the US Pacific Northwest: Scientific Data, v. 5, article 180165, at https://doi.org/10.1038/sdata.2018.165. |
Identifying microclimate tree seedling refugia in post-wildfire landscapes | C. Marsh, D. Krofcheck, M. D. Hurteau | 2022 | Marsh, C., Krofcheck, D., and Hurteau, M.D., 2022, Identifying microclimate tree seedling refugia in post-wildfire landscapes: Agricultural and Forest Meteorology, v. 313, article 108741, at https://doi.org/10.1016/j.agrformet.2021.108741. |
Planted seedling survival in a post-wildfire landscape—From experimental planting to predictive probabilistic surfaces | C. Marsh, J. L. Crockett, D. Krofcheck, A. Keyser, C. D. Allen, M. Litvak, M. D. Hurteau | 2022 | Marsh, C., Crockett, J.L., Krofcheck, D., Keyser, A., Allen, C.D., Litvak, M., and Hurteau, M.D., 2022, Planted seedling survival in a post-wildfire landscape—From experimental planting to predictive probabilistic surfaces: Forest Ecology and Management, v. 525, article 120524, at https://doi.org/10.1016/j.foreco.2022.120524. |
Effects of nurse shrubs and biochar on planted conifer seedling survival and growth in a high-severity burn patch in New Mexico, USA | C. Marsh, J. C. Blankinship, M. D. Hurteau | 2023 | Marsh, C., Blankinship, J.C., and Hurteau, M.D., 2023, Effects of nurse shrubs and biochar on planted conifer seedling survival and growth in a high-severity burn patch in New Mexico, USA: Forest Ecology and Management, v. 537, article 120971, at https://doi.org/10.1016/j.foreco.2023.120971. |
Evaluating immaturity risk in young stands of the serotinous knobcone pine (Pinus attenuata) | K. F. Marlin, D. F. Greene, J. M. Kane, M. Reilly, B. D. Madurapperuma | 2024 | Marlin, K.F., Greene, D.F., Kane, J.M., Reilly, M., and Madurapperuma, B.D., 2024, Evaluating immaturity risk in young stands of the serotinous knobcone pine (Pinus attenuata): Ecosphere, v. 15, no. 2, article e4765, at https://doi.org/10.1002/ecs2.4765. |
Quaking aspen regeneration following prescribed fire in Lassen Volcanic National Park, California, USA | E. Q. Margolis, C. A. Farris | 2014 | Margolis, E.Q., and Farris, C.A., 2014, Quaking aspen regeneration following prescribed fire in Lassen Volcanic National Park, California, USA: Fire Ecology, v. 10, no. 3, p. 14–26, at https://doi.org/10.4996/fireecology.1003014. |
Contrasting human influences and macro-environmental factors on fire activity inside and outside protected areas of North America | N. Mansuy, C. Miller, M. A. Parisien, S. A. Parks, E. Batllori, M. A. Moritz | 2019 | Mansuy, N., Miller, C., Parisien, M.A., Parks, S.A., Batllori, E., and Moritz, M.A., 2019, Contrasting human influences and macro-environmental factors on fire activity inside and outside protected areas of North America: Environmental Research Letters, v. 14, no. 6, article 064007, at https://doi.org/10.1088/1748-9326/ab1bc5. |
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Mixed-severity fire fosters heterogeneous spatial patterns of conifer regeneration in a dry conifer forest | S. L. Malone, P. J. Fornwalt, M. A. Battaglia, M. E. Chambers, J. M. Iniguez, C. H. Sieg | 2018 | Malone, S.L., Fornwalt, P.J., Battaglia, M.A., Chambers, M.E., Iniguez, J.M., and Sieg, C.H., 2018, Mixed-severity fire fosters heterogeneous spatial patterns of conifer regeneration in a dry conifer forest: Forests, v. 9, no. 1, article 45, at https://doi.org/10.3390/f9010045. |
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Fuel connectivity, burn severity, and seedbank survivorship drive ecosystem transformation in a semiarid shrubland | A. L. Mahood, M. J. Koontz, J. K. Balch | 2023 | Mahood, A.L., Koontz, M.J., and Balch, J.K., 2023, Fuel connectivity, burn severity, and seedbank survivorship drive ecosystem transformation in a semiarid shrubland: Ecology, v. 104, no. 3, article e3968, at https://doi.org/10.1002/ecy.3968. |
Repeated fires reduce plant diversity in low-elevation Wyoming big sagebrush ecosystems (1984–2014) | A. L. Mahood, J. K. Balch | 2019 | Mahood, A.L., and Balch, J.K., 2019, Repeated fires reduce plant diversity in low-elevation Wyoming big sagebrush ecosystems (1984–2014): Ecosphere, v. 10, no. 2, article e02591, at https://doi.org/10.1002/ecs2.2591. |
A comprehensive data-based assessment of forest ecosystem carbon stocks in the US 1907–2012 | A. Magerl, J. Le Noë, K.-H. Erb, M. Bhan, S. Gingrich | 2019 | Magerl, A., Le Noë, J., Erb, K.-H., Bhan, M., and Gingrich, S., 2019, A comprehensive data-based assessment of forest ecosystem carbon stocks in the US 1907–2012: Environmental Research Letters, v. 14, no. 12, article 125015, at https://doi.org/10.1088/1748-9326/ab5cb6. |
Investigating the contribution of the coarse fraction to total pyrogenic carbon stocks in forest soil | B. Maestrini, J. R. Miesel | 2018 | Maestrini, B., and Miesel, J.R., 2018, Investigating the contribution of the coarse fraction to total pyrogenic carbon stocks in forest soil: Organic Geochemistry, v. 125, p. 161–164, at https://doi.org/10.1016/j.orggeochem.2018.09.009. |
Fire severity alters the distribution of pyrogenic carbon stocks across ecosystem pools in a Californian mixed-conifer forest | B. Maestrini, E. C. Alvey, M. D. Hurteau, H. Safford, J. R. Miesel | 2017 | Maestrini, B., Alvey, E.C., Hurteau, M.D., Safford, H., and Miesel, J.R., 2017, Fire severity alters the distribution of pyrogenic carbon stocks across ecosystem pools in a Californian mixed-conifer forest: Journal of Geophysical Research—Biogeosciences, v. 122, no. 9, p. 2338–2355, at https://doi.org/10.1002/2017jg003832. |
Using dynamic, fuels-based fire probability maps to reduce large wildfires in the Great Basin | J. D. Maestas, J. T. Smith, B. W. Allred, D. E. Naugle, M. O. Jones, C. O'Connor, C. S. Boyd, K. W. Davies, M. R. Crist, A. C. Olsen | 2023 | Maestas, J.D., Smith, J.T., Allred, B.W., Naugle, D.E., Jones, M.O., O'Connor, C., Boyd, C.S., Davies, K.W., Crist, M.R., and Olsen, A.C., 2023, Using dynamic, fuels-based fire probability maps to reduce large wildfires in the Great Basin: Rangeland Ecology & Management, v. 89, p. 33–41, at https://doi.org/10.1016/j.rama.2022.08.002. |
The impacts of climate and wildfire on ecosystem gross primary productivity in Alaska | N. Madani, N. C. Parazoo, J. S. Kimball, R. H. Reichle, A. Chatterjee, J. D. Watts, S. Saatchi, Z. Liu, A. Endsley, T. Tagesson, B. M. Rogers, L. Xu, J. A. Wang, T. Magney, C. E. Miller | 2021 | Madani, N., Parazoo, N.C., Kimball, J.S., Reichle, R.H., Chatterjee, A., Watts, J.D., Saatchi, S., Liu, Z., Endsley, A., et al., 2021, The impacts of climate and wildfire on ecosystem gross primary productivity in Alaska: Journal of Geophysical Research—Biogeosciences, v. 126, no. 6, article e2020JG006078, at https://doi.org/10.1029/2020JG006078. |
Quantifying increased fire risk in California in response to different levels of warming and drying | S. Madadgar, M. Sadegh, F. Chiang, E. Ragno, A. AghaKouchak | 2020 | Madadgar, S., Sadegh, M., Chiang, F., Ragno, E., and AghaKouchak, A., 2020, Quantifying increased fire risk in California in response to different levels of warming and drying: Stochastic Environmental Research and Risk Assessment, v. 34, no. 12, p. 2023–2031, at https://doi.org/10.1007/s00477-020-01885-y. |
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Spatially explicit carrying capacity estimates to inform species specific recovery objectives—Grizzly bear (Ursus arctos) recovery in the north Cascades | A. L. Lyons, W. L. Gaines, P. H. Singleton, W. F. Kasworm, M. F. Proctor, J. Begley | 2018 | Lyons, A.L., Gaines, W.L., Singleton, P.H., Kasworm, W.F., Proctor, M.F., and Begley, J., 2018, Spatially explicit carrying capacity estimates to inform species specific recovery objectives—Grizzly bear (Ursus arctos) recovery in the north Cascades: Biological Conservation, v. 222, p. 21–32, at https://doi.org/10.1016/j.biocon.2018.03.027. |
Climate change, wildfire, and past forest management challenge conservation of Canada lynx in Washington, USA | A. L. Lyons, W. L. Gaines, J. C. Lewis, B. T. Maletzke, D. Werntz, D. H. Thornton, P. F. Hessburg, J. Begley, C. Vanbianchi, T. W. King, G. Blatz, S. Fitkin | 2023 | Lyons, A.L., Gaines, W.L., Lewis, J.C., Maletzke, B.T., Werntz, D., Thornton, D.H., Hessburg, P.F., Begley, J., Vanbianchi, C., et al., 2023, Climate change, wildfire, and past forest management challenge conservation of Canada lynx in Washington, USA: The Journal of Wildlife Management, v. 87, no. 5, article e22410, at https://doi.org/10.1002/jwmg.22410. |
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Cascading effects of climate change and wildfire on a subarctic lake—A 20?year case study of watershed change | A. S. Larsen, D. L. Rupp, D. K. Swanson, K. R. Hill | 2023 | Larsen, A.S., Rupp, D.L., Swanson, D.K., and Hill, K.R., 2023, Cascading effects of climate change and wildfire on a subarctic lake—A 20?year case study of watershed change: Ecosphere, v. 14, no. 7, article e4558, at https://doi.org/10.1002/ecs2.4558. |
Wildland fire emissions, carbon, and climate—U.S. emissions inventories | N. K. Larkin, S. M. Raffuse, T. M. Strand | 2014 | Larkin, N.K., Raffuse, S.M., and Strand, T.M., 2014, Wildland fire emissions, carbon, and climate—U.S. emissions inventories: Forest Ecology and Management, v. 317, p. 61–69, at https://doi.org/10.1016/j.foreco.2013.09.012. |
The Comprehensive Fire Information Reconciled Emissions (CFIRE) Inventory—Wildland fire emissions developed for the 2011 and 2014 U.S. National Emissions Inventory | N. K. Larkin, S. M. Raffuse, S. Huang, N. Pavlovic, P. Lahm, V. Rao | 2020 | Larkin, N.K., Raffuse, S.M., Huang, S., Pavlovic, N., Lahm, P., and Rao, V., 2020, The Comprehensive Fire Information Reconciled Emissions (CFIRE) Inventory—Wildland fire emissions developed for the 2011 and 2014 U.S. National Emissions Inventory: Journal of the Air & Waste Management Association, v. 70, no. 11, p. 1165–1185 at https://doi.org/10.1080/10962247.2020.1802365. |
Recent warming reverses forty-year decline in catastrophic lake drainage and hastens gradual lake drainage across northern Alaska | M. J. Lara, Y. Chen, B. M. Jones | 2021 | Lara, M.J., Chen, Y., and Jones, B.M., 2021, Recent warming reverses forty-year decline in catastrophic lake drainage and hastens gradual lake drainage across northern Alaska: Environmental Research Letters, v. 16, article 124019, at https://doi.org/10.1088/1748-9326/ac3602. |
Defining extreme wildland fires using geospatial and ancillary metrics | K. O. Lannom, W. T. Tinkham, A. M. S. Smith, J. Abatzoglou, B. A. Newingham, T. E. Hall, P. Morgan, E. K. Strand, T. B. Paveglio, J. W. Anderson, A. M. Sparks | 2014 | Lannom, K.O., Tinkham, W.T., Smith, A.M.S., Abatzoglou, J., Newingham, B.A., Hall, T.E., Morgan, P., Strand, E.K., Paveglio, T.B., et al., 2014, Defining extreme wildland fires using geospatial and ancillary metrics: International Journal of Wildland Fire, v. 23, no. 3, p. 322–337, at https://doi.org/10.1071/WF13065. |
The impact of the 2016 Fort McMurray Horse River Wildfire on ambient air pollution levels in the Athabasca Oil Sands Region, Alberta, Canada | M. S. Landis, E. S. Edgerton, E. M. White, G. R. Wentworth, A. P. Sullivan, A. M. Dillner | 2018 | Landis, M.S., Edgerton, E.S., White, E.M., Wentworth, G.R., Sullivan, A.P., and Dillner, A.M., 2018, The impact of the 2016 Fort McMurray Horse River Wildfire on ambient air pollution levels in the Athabasca Oil Sands Region, Alberta, Canada: Science of the Total Environment, v. 618, p. 1665–1676, at https://doi.org/10.1016/j.scitotenv.2017.10.008. |
Relationships among burn severity, forest canopy structure and bat activity from spring burns in oak-hickory forests | M. J. Lacki, L. E. Dodd, N. S. Skowronski, M. B. Dickinson, L. K. Rieske | 2017 | Lacki, M.J., Dodd, L.E., Skowronski, N.S., Dickinson, M.B., and Rieske, L.K., 2017, Relationships among burn severity, forest canopy structure and bat activity from spring burns in oak-hickory forests: International Journal of Wildland Fire, v. 26, no. 11, p. 963–972, at https://doi.org/10.1071/Wf16159. |
Remote sensing of forest burnt area, burn severity, and post-fire recovery—A review | E. Kurbanov, O. Vorobev, S. Lezhnin, J. Sha, J. Wang, X. Li, J. Cole, D. Dergunov, Y. Wang | 2022 | Kurbanov, E., Vorobev, O., Lezhnin, S., Sha, J., Wang, J., Li, X., Cole, J., Dergunov, D., and Wang, Y., 2022, Remote sensing of forest burnt area, burn severity, and post-fire recovery—A review: Remote Sensing, v. 14, no. 19, article 4714, at https://doi.org/10.3390/rs14194714. |
The Spatially Adaptable Filter for Error Reduction (SAFER) process—Remote sensing-based LANDFIRE disturbance mapping updates | S. S. Kumar, B. Tolk, R. Dittmeier, J. J. Picotte, I. La Puma, B. Peterson, T. D. Hatten | 2024 | Kumar, S.S., Tolk, B., Dittmeier, R., Picotte, J.J., La Puma, I., Peterson, B., and Hatten, T.D., 2024, The Spatially Adaptable Filter for Error Reduction (SAFER) process—Remote sensing-based LANDFIRE disturbance mapping updates: Fire, v. 7, no. 2, article 51, at https://doi.org/10.3390/fire7020051. |
Examining the existing definitions of wildland?urban interface for California | M. Kumar, S. Li, P. Nguyen, T. Banerjee | 2022 | Kumar, M., Li, S., Nguyen, P., and Banerjee, T., 2022, Examining the existing definitions of wildland?urban interface for California: Ecosphere, v. 13, no. 12, article e4306, at https://doi.org/10.1002/ecs2.4306. |
Scales of connectivity within stream temperature networks of the Clackamas River Basin, Oregon | M. Krochta, H. Chang | in press | Krochta, M., and Chang, H., in press, Scales of connectivity within stream temperature networks of the Clackamas River Basin, Oregon: Annals of the American Association of Geographers, at https://doi.org/10.1080/24694452.2023.2289981. |
Topographic and fire weather controls of fire refugia in forested ecosystems of northwestern North America | M. A. Krawchuk, S. L. Haire, J. Coop, M.-A. Parisien, E. Whitman, G. Chong, C. Miller | 2016 | Krawchuk, M.A., Haire, S.L., Coop, J., Parisien, M.-A., Whitman, E., Chong, G., and Miller, C., 2016, Topographic and fire weather controls of fire refugia in forested ecosystems of northwestern North America: Ecosphere, v. 7, no. 12, article e01632, at https://doi.org/10.1002/ecs2.1632. |
Evolving paradigms of aspen ecology and management—Impacts of stand condition and fire severity on vegetation dynamics | K. D. Krasnow, S. L. Stephens | 2015 | Krasnow, K.D., and Stephens, S.L., 2015, Evolving paradigms of aspen ecology and management—Impacts of stand condition and fire severity on vegetation dynamics: Ecosphere, v. 6, no. 1, article 12, at https://doi.org/10.1890/ES14-00354.1. |
Where wildfires destroy buildings in the US relative to the wildland-urban interface and national fire outreach programs | H. A. Kramer, M. H. Mockrin, P. M. Alexandre, S. I. Stewart, V. C. Radeloff | 2018 | Kramer, H.A., Mockrin, M.H., Alexandre, P.M., Stewart, S.I., and Radeloff, V.C., 2018, Where wildfires destroy buildings in the US relative to the wildland-urban interface and national fire outreach programs: International Journal of Wildland Fire, v. 27, no. 5, p. 329–341, at https://doi.org/10.1071/Wf17135. |
High wildfire damage in interface communities in California | H. A. Kramer, M. H. Mockrin, P. M. Alexandre, V. C. Radeloff | 2019 | Kramer, H.A., Mockrin, M.H., Alexandre, P.M., and Radeloff, V.C., 2019, High wildfire damage in interface communities in California: International Journal of Wildland Fire, v. 28, no. 9, p. 641–650, at https://doi.org/10.1071/Wf18108. |
Post-wildfire rebuilding and new development in California indicates minimal adaptation to fire risk | H. A. Kramer, V. Butsic, M. H. Mockrin, C. Ramirez-Reyes, P. M. Alexandre, V. C. Radeloff | 2021 | Kramer, H.A., Butsic, V., Mockrin, M.H., Ramirez-Reyes, C., Alexandre, P.M., and Radeloff, V.C., 2021, Post-wildfire rebuilding and new development in California indicates minimal adaptation to fire risk: Land Use Policy, v. 107, article 105502, at https://doi.org/10.1016/j.landusepol.2021.105502. |
California spotted owl habitat selection in a fire-managed landscape suggests conservation benefit of restoring historical fire regimes | A. Kramer, G. M. Jones, S. A. Whitmore, J. J. Keane, F. A. Atuo, B. P. Dotters, S. C. Sawyer, S. L. Stock, R. J. Gutierrez, M. Z. Peery | 2021 | Kramer, A., Jones, G.M., Whitmore, S.A., Keane, J.J., Atuo, F.A., Dotters, B.P., Sawyer, S.C., Stock, S.L., Gutierrez, R.J., and Peery, M.Z., 2021, California spotted owl habitat selection in a fire-managed landscape suggests conservation benefit of restoring historical fire regimes: Forest Ecology and Management, v. 479, article 118576, at https://doi.org/10.1016/j.foreco.2020.118576. |
Spatial signatures of biological soil crusts and community level self-organization in drylands | D. Kozar, B. Weber, Y. Zhang, X. Dong | in press | Kozar, D., Weber, B., Zhang, Y., and Dong, X., in press, Spatial signatures of biological soil crusts and community level self-organization in drylands: Ecosystems, at https://doi.org/10.1007/s10021-023-00898-2. |
Wildfire impacts on western United States snowpacks | A. L. Koshkin, B. J. Hatchett, A. W. Nolin | 2022 | Koshkin, A.L., Hatchett, B.J., and Nolin, A.W., 2022, Wildfire impacts on western United States snowpacks: Frontiers in Water, v. 4, article 971271, at https://doi.org/10.3389/frwa.2022.971271. |
Influence of uncertainties in burned area estimates on modeled wildland fire PM2.5 and ozone pollution in the contiguous U.S | S. N. Koplitz, C. G. Nolte, G. A. Pouliot, J. M. Vukovich, J. Beidler | 2018 | Koplitz, S.N., Nolte, C.G., Pouliot, G.A., Vukovich, J.M., and Beidler, J., 2018, Influence of uncertainties in burned area estimates on modeled wildland fire PM2.5 and ozone pollution in the contiguous U.S: Atmospheric Environment, v. 191, p. 328–339, at https://doi.org/10.1016/j.atmosenv.2018.08.020. |
Local forest structure variability increases resilience to wildfire in dry western US coniferous forests | M. J. Koontz, M. P. North, C. M. Werner, S. E. Fick, A. M. Latimer | 2020 | Koontz, M.J., North, M.P., Werner, C.M., Fick, S.E., and Latimer, A.M., 2020, Local forest structure variability increases resilience to wildfire in dry western US coniferous forests: Ecology Letters, v. 23, no. 3, p. 483–494, at https://doi.org/10.1111/ele.13447. |
Stream thermal responses to wildfire in the Pacific Northwest | E. D. Koontz, E. A. Steel, J. D. Olden | 2018 | Koontz, E.D., Steel, E.A., and Olden, J.D., 2018, Stream thermal responses to wildfire in the Pacific Northwest: Freshwater Science, v. 37, no. 4, p. 731–746, at https://doi.org/10.1086/700403. |
Viewsheds and recreation demand—Approaches for capturing visual qualities of the landscape post-fire | S. H. Kolstoe, A. R. Kaminski, A. T. Maher | 2023 | Kolstoe, S.H., Kaminski, A.R., and Maher, A.T., 2023, Viewsheds and recreation demand—Approaches for capturing visual qualities of the landscape post-fire: Western Economics Forum, v. 21, no. 2, p. 24–33, at https://doi.org/10.22004/ag.econ.339201. |
Limitations and utilisation of Monitoring Trends in Burn Severity products for assessing wildfire severity in the USA | C. A. Kolden, A. M. S. Smith, J. T. Abatzoglou | 2015 | Kolden, C.A., Smith, A.M.S., and Abatzoglou, J.T., 2015, Limitations and utilisation of Monitoring Trends in Burn Severity products for assessing wildfire severity in the USA: International Journal of Wildland Fire, v. 24, no. 7, p. 1023–1028, at https://doi.org/10.1071/Wf15082. |
Mapped versus actual burned area within wildfire perimeters—Characterizing the unburned | C. A. Kolden, J. A. Lutz, C. H. Key, J. T. Kane, J. W. van Wagtendonk | 2012 | Kolden, C.A., Lutz, J.A., Key, C.H., Kane, J.T., and van Wagtendonk, J.W., 2012, Mapped versus actual burned area within wildfire perimeters—Characterizing the unburned: Forest Ecology and Management, v. 286, p. 38–47, at https://doi.org/10.1016/j.foreco.2012.08.020. |
Estimating national costs, benefits, and potential for cellulosic ethanol production from forest thinnings | M. Kocoloski, W. Michael Griffin, H. Scott Matthews | 2011 | Kocoloski, M., Michael Griffin, W., and Scott Matthews, H., 2011, Estimating national costs, benefits, and potential for cellulosic ethanol production from forest thinnings: Biomass and Bioenergy, v. 35, no. 5, p. 2133–2142, at https://doi.org/10.1016/j.biombioe.2011.02.010. |
Indicators of climate change in Idaho—An assessment framework for coupling biophysical change and social perception | P. Z. Klos, J. T. Abatzoglou, A. Bean, J. Blades, M. A. Clark, M. Dodd, T. E. Hall, A. Haruch, P. E. Higuera, J. D. Holbrook, V. S. Jansen, K. Kemp, A. Lankford, T. E. Link, T. Magney, A. J. H. Meddens, L. Mitchell, B. Moore, P. Morgan, B. A. Newingham, R. J. Niemeyer, B. Soderquist, A. A. Suazo, K. T. Vierling, V. Walden, C. Walsh | 2015 | Klos, P.Z., Abatzoglou, J.T., Bean, A., Blades, J., Clark, M.A., Dodd, M., Hall, T.E., Haruch, A., Higuera, P.E., et al., 2015, Indicators of climate change in Idaho—An assessment framework for coupling biophysical change and social perception: Weather, Climate, and Society, v. 7, no. 3, p. 238–254, at https://doi.org/10.1175/WCAS-D-13-00070.1. |
Contrasting geographic patterns of ignition probability and burn severity in the Mojave Desert | R. Klinger, E. C. Underwood, R. McKinley, M. L. Brooks | 2021 | Klinger, R., Underwood, E.C., McKinley, R., and Brooks, M.L., 2021, Contrasting geographic patterns of ignition probability and burn severity in the Mojave Desert: Frontiers in Ecology and Evolution, v. 9, article 593167, at https://doi.org/10.3389/fevo.2021.593167. |
An evaluation of remotely sensed indices for quantifying burn severity in arid ecoregions | R. Klinger, R. McKinley, M. Brooks | 2019 | Klinger, R., McKinley, R., and Brooks, M., 2019, An evaluation of remotely sensed indices for quantifying burn severity in arid ecoregions: International Journal of Wildland Fire, v. 28, no. 12, p. 951–968, at https://doi.org/10.1071/WF19025. |
Alternative pathways to landscape transformation—Invasive grasses, burn severity and fire frequency in arid ecosystems | R. Klinger, M. Brooks | 2017 | Klinger, R., and Brooks, M., 2017, Alternative pathways to landscape transformation—Invasive grasses, burn severity and fire frequency in arid ecosystems: Journal of Ecology, v. 105, no. 6, p. 1521–1533, at https://doi.org/10.1111/1365-2745.12863. |
Quantifying aspects of rangeland health at watershed scales in Colorado using remotely sensed data products | N. J. Kleist, C. T. Domschke, S. E. Litschert, J. H. Seim, S. K. Carter | 2022 | Kleist, N.J., Domschke, C.T., Litschert, S.E., Seim, J.H., and Carter, S.K., 2022, Quantifying aspects of rangeland health at watershed scales in Colorado using remotely sensed data products: Rangelands, v. 44, no. 6, p. 398–410, at https://doi.org/10.1016/j.rala.2022.09.003. |
Fire and flood expand the floodplain shifting habitat mosaic concept | W. J. Kleindl, M. C. Rains, L. A. Marshall, F. R. Hauer | 2015 | Kleindl, W.J., Rains, M.C., Marshall, L.A., and Hauer, F.R., 2015, Fire and flood expand the floodplain shifting habitat mosaic concept: Freshwater Science, v. 34, no. 4, p. 1366–1382, at https://doi.org/10.1086/684016. |
Range?wide occupancy trends for the Mojave Desert tortoise (Gopherus agassizi) | A. M. Kissel, B. Wallace, J. Anderson, B. G. Dickson, K. Van Neste, V. Landau, R. C. Averill?Murray, L. J. Allison, A. Fesnock | 2023 | Kissel, A.M., Wallace, B., Anderson, J., Dickson, B.G., Van Neste, K., Landau, V., Averill?Murray, R.C., Allison, L.J., and Fesnock, A., 2023, Range?wide occupancy trends for the Mojave Desert tortoise (Gopherus agassizi): Ecosphere, v. 14, no. 3, article e4462, at https://doi.org/10.1002/ecs2.4462. |
Distinguishing between live and dead standing tree biomass on the North Rim of Grand Canyon National Park, USA using small-footprint lidar data | Y. Kim, Z. Yang, W. B. Cohen, D. Pflugmacher, C. L. Lauver, J. L. Vankat | 2009 | Kim, Y., Yang, Z., Cohen, W.B., Pflugmacher, D., Lauver, C.L., and Vankat, J.L., 2009, Distinguishing between live and dead standing tree biomass on the North Rim of Grand Canyon National Park, USA using small-footprint lidar data: Remote Sensing of Environment, v. 113, no. 11, p. 2499–2510, at https://doi.org/10.1016/j.rse.2009.07.010. |
Applicability assessment of a spatiotemporal geostatistical fusion model for disaster monitoring—Two cases of flood and wildfire | Y. Kim | 2022 | Kim, Y., 2022, Applicability assessment of a spatiotemporal geostatistical fusion model for disaster monitoring—Two cases of flood and wildfire: Remote Sensing, v. 14, no. 24, article 6204, at https://doi.org/10.3390/rs14246204. |
Post-wildfire regeneration in a sky-island mixed- conifer ecosystem of the North American Great Basin | M. Kilpatrick, F. Biondi | 2020 | Kilpatrick, M., and Biondi, F., 2020, Post-wildfire regeneration in a sky-island mixed- conifer ecosystem of the North American Great Basin: Forests, v. 11, no. 9, article 900, at https://doi.org/10.3390/f11090900. |
The need of monitoring forest fires through burned area mapping in Indonesia | R. Khoirunisa | 2021 | Khoirunisa, R., 2021, The need of monitoring forest fires through burned area mapping in Indonesia: Geographica—Science & Education Journal, v. 3, no. 1, p. 16–23, at https://usnsj.com/index.php/geographica/article/view/1423. |
Predicting increasing high severity area burned for three forested regions in the western United States using extreme value theory | A. R. Keyser, A. L. Westerling | 2019 | Keyser, A.R., and Westerling, A.L., 2019, Predicting increasing high severity area burned for three forested regions in the western United States using extreme value theory: Forest Ecology and Management, v. 432, p. 694–706, at https://doi.org/10.1016/j.foreco.2018.09.027. |
Simulated increases in fire activity reinforce shrub conversion in a southwestern US Forest | A. R. Keyser, D. J. Krofcheck, C. C. Remy, C. D. Allen, M. D. Hurteau | 2020 | Keyser, A.R., Krofcheck, D.J., Remy, C.C., Allen, C.D., and Hurteau, M.D., 2020, Simulated increases in fire activity reinforce shrub conversion in a southwestern US Forest: Ecosystems, v. 23, no. 8, p. 1702–1713, at https://doi.org/10.1007/s10021-020-00498-4. |
Climate drives inter-annual variability in probability of high severity fire occurrence in the western United States | A. Keyser, A. L. Westerling | 2017 | Keyser, A., and Westerling, A.L., 2017, Climate drives inter-annual variability in probability of high severity fire occurrence in the western United States: Environmental Research Letters, v. 12, no. 6, article 065003, at https://doi.org/10.1088/1748-9326/aa6b10. |
The nativity and distribution of the cryptic invader Phalaris arundinacea (reed canarygrass) in riparian areas of the Columbia and Missouri river basins | K. M. Kettenring, D. R. Menuz, K. E. Mock | 2018 | Kettenring, K.M., Menuz, D.R., and Mock, K.E., 2018, The nativity and distribution of the cryptic invader Phalaris arundinacea (reed canarygrass) in riparian areas of the Columbia and Missouri river basins: Wetlands, v. 39, no. 1, p. 55–66, at https://doi.org/10.1007/s13157-018-1074-x. |
Differential response of native Arizona gray squirrels and introduced Abert's squirrels to a mosaic of burn severities | S. L. Ketcham, J. L. Koprowski, D. A. Falk | 2017 | Ketcham, S.L., Koprowski, J.L., and Falk, D.A., 2017, Differential response of native Arizona gray squirrels and introduced Abert's squirrels to a mosaic of burn severities: Mammal Study, v. 42, no. 4, p. 247–258, at https://doi.org/10.3106/041.042.0407. |
Spatial and temporal patterns of forest disturbance and regrowth within the area of the Northwest Forest Plan | R. E. Kennedy, Z. Yang, W. B. Cohen, E. Pfaff, J. Braaten, P. Nelson | 2012 | Kennedy, R.E., Yang, Z., Cohen, W.B., Pfaff, E., Braaten, J., and Nelson, P., 2012, Spatial and temporal patterns of forest disturbance and regrowth within the area of the Northwest Forest Plan: Remote Sensing of Environment, v. 122, p. 117–133, at https://doi.org/10.1016/j.rse.2011.09.024. |
Attribution of disturbance change agent from Landsat time-series in support of habitat monitoring in the Puget Sound region, USA | R. E. Kennedy, Z. Yang, J. Braaten, C. Copass, N. Antonova, C. Jordan, P. Nelson | 2015 | Kennedy, R.E., Yang, Z., Braaten, J., Copass, C., Antonova, N., Jordan, C., and Nelson, P., 2015, Attribution of disturbance change agent from Landsat time-series in support of habitat monitoring in the Puget Sound region, USA: Remote Sensing of Environment, v. 166, p. 271–285, at https://doi.org/10.1016/j.rse.2015.05.005. |
Choose your neighborhood wisely—Implications of subsampling and autocorrelation structure in simultaneous autoregression models for landscape ecology | M. C. Kennedy, S. J. Prichard | 2017 | Kennedy, M.C., and Prichard, S.J., 2017, Choose your neighborhood wisely—Implications of subsampling and autocorrelation structure in simultaneous autoregression models for landscape ecology: Landscape Ecology, v. 32, no. 5, p. 945–952, at https://doi.org/10.1007/s10980-017-0499-6. |
Climate will increasingly determine post-fire tree regeneration success in low-elevation forests, Northern Rockies, USA | K. B. Kemp, P. E. Higuera, P. Morgan, J. T. Abatzoglou | 2019 | Kemp, K.B., Higuera, P.E., Morgan, P., and Abatzoglou, J.T., 2019, Climate will increasingly determine post-fire tree regeneration success in low-elevation forests, Northern Rockies, USA: Ecosphere, v. 10, no. 1, article e02568, at https://doi.org/10.1002/ecs2.2568. |
Fire legacies impact conifer regeneration across environmental gradients in the U.S. Northern Rockies | K. B. Kemp, P. E. Higuera, P. Morgan | 2015 | Kemp, K.B., Higuera, P.E., and Morgan, P., 2015, Fire legacies impact conifer regeneration across environmental gradients in the U.S. Northern Rockies: Landscape Ecology, v. 31, no. 3, p. 619–636, at https://doi.org/10.1007/s10980-015-0268-3. |
Prescribed burns as a tool to mitigate future wildfire smoke exposure—Lessons for states and rural environmental justice communities | M. M. Kelp, M. C. Carroll, T. Liu, R. M. Yantosca, H. E. Hockenberry, L. J. Mickley | 2023 | Kelp, M.M., Carroll, M.C., Liu, T., Yantosca, R.M., Hockenberry, H.E., and Mickley, L.J., 2023, Prescribed burns as a tool to mitigate future wildfire smoke exposure—Lessons for states and rural environmental justice communities: Earth's Future, v. 11, no. 6, article e2022EF003468, at https://doi.org/10.1029/2022ef003468. |
The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral | J. E. Keeley, T. J. Brennan, A. D. Syphard | 2022 | Keeley, J.E., Brennan, T.J., and Syphard, A.D., 2022, The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral: Ecosphere, v. 13, no. 8, article e4203, at https://doi.org/10.1002/ecs2.4203. |
The construction of probabilistic wildfire risk estimates for individual real estate parcels for the contiguous United States | E. J. Kearns, D. Saah, C. R. Levine, C. Lautenberger, O. M. Doherty, J. R. Porter, M. Amodeo, C. Rudeen, K. D. Woodward, G. W. Johnson, K. Markert, E. Shu, N. Freeman, M. Bauer, K. Lai, H. Hsieh, B. Wilson, B. McClenny, A. McMahon, F. Chishtie | 2022 | Kearns, E.J., Saah, D., Levine, C.R., Lautenberger, C., Doherty, O.M., Porter, J.R., Amodeo, M., Rudeen, C., Woodward, K.D., et al., 2022, The construction of probabilistic wildfire risk estimates for individual real estate parcels for the contiguous United States: Fire, v. 5, no. 4, article 117, at https://doi.org/10.3390/fire5040117. |
Evaluating the performance and mapping of three fuel classification systems using Forest Inventory and Analysis surface fuel measurements | R. E. Keane, J. M. Herynk, C. Toney, S. P. Urbanski, D. C. Lutes, R. D. Ottmar | 2013 | Keane, R.E., Herynk, J.M., Toney, C., Urbanski, S.P., Lutes, D.C., and Ottmar, R.D., 2013, Evaluating the performance and mapping of three fuel classification systems using Forest Inventory and Analysis surface fuel measurements: Forest Ecology and Management, v. 305, p. 248–263, at https://doi.org/10.1016/j.foreco.2013.06.001. |
Forecasting the frequency and magnitude of postfire debris flows across southern California | J. W. Kean, D. M. Staley | 2021 | Kean, J.W., and Staley, D.M., 2021, Forecasting the frequency and magnitude of postfire debris flows across southern California: Earth's Future, v. 9, no. 3, article e2020EF001735, at https://doi.org/10.1029/2020ef001735. |
Quantifying burned area for North American forests—Implications for direct reduction of carbon stocks | E. S. Kasischke, T. Loboda, L. Giglio, N. H. F. French, E. E. Hoy, B. De Jong, D. Riano | 2011 | Kasischke, E.S., Loboda, T., Giglio, L., French, N.H.F., Hoy, E.E., De Jong, B., and Riano, D., 2011, Quantifying burned area for North American forests—Implications for direct reduction of carbon stocks: Journal of Geophysical Research—Biogeosciences, v. 116, no. 4, article G04003, at https://doi.org/10.1029/2011JG001707. |
Controls on carbon consumption during Alaskan wildland fires | E. S. Kasischke, E. E. Hoy | 2012 | Kasischke, E.S., and Hoy, E.E., 2012, Controls on carbon consumption during Alaskan wildland fires: Global Change Biology, v. 18, no. 2, p. 685–699, at https://doi.org/10.1111/j.1365-2486.2011.02573.x. |
Integrating satellite imagery with simulation modeling to improve burn severity mapping | E. C. Karau, P. G. Sikkink, R. E. Keane, G. K. Dillon | 2014 | Karau, E.C., Sikkink, P.G., Keane, R.E., and Dillon, G.K., 2014, Integrating satellite imagery with simulation modeling to improve burn severity mapping: Environmental Management, v. 54, no. 1, p. 98–111, at https://doi.org/10.1007/s00267-014-0279-x. |
Assessing fire effects on forest spatial structure using a fusion of Landsat and airborne LiDAR data in Yosemite National Park | V. R. Kane, M. P. North, J. A. Lutz, D. J. Churchill, S. L. Roberts, D. F. Smith, R. J. McGaughey, J. T. Kane, M. L. Brooks | 2014 | Kane, V.R., North, M.P., Lutz, J.A., Churchill, D.J., Roberts, S.L., Smith, D.F., McGaughey, R.J., Kane, J.T., and Brooks, M.L., 2014, Assessing fire effects on forest spatial structure using a fusion of Landsat and airborne LiDAR data in Yosemite National Park: Remote Sensing of Environment, v. 151, p. 89–101, at https://doi.org/10.1016/j.rse.2013.07.041. |
Landscape-scale effects of fire severity on mixed-conifer and red fir forest structure in Yosemite National Park | V. R. Kane, J. A. Lutz, S. L. Roberts, D. F. Smith, R. J. McGaughey, N. A. Povak, M. L. Brooks | 2013 | Kane, V.R., Lutz, J.A., Roberts, S.L., Smith, D.F., McGaughey, R.J., Povak, N.A., and Brooks, M.L., 2013, Landscape-scale effects of fire severity on mixed-conifer and red fir forest structure in Yosemite National Park: Forest Ecology and Management, v. 287, p. 17–31, at https://doi.org/10.1016/j.foreco.2012.08.044. |
Water balance and topography predict fire and forest structure patterns | V. R. Kane, J. A. Lutz, C. Alina Cansler, N. A. Povak, D. J. Churchill, D. F. Smith, J. T. Kane, M. P. North | 2015 | Kane, V.R., Lutz, J.A., Alina Cansler, C., Povak, N.A., Churchill, D.J., Smith, D.F., Kane, J.T., and North, M.P., 2015, Water balance and topography predict fire and forest structure patterns: Forest Ecology and Management, v. 338, p. 1–13, at https://doi.org/10.1016/j.foreco.2014.10.038. |
Mixed severity fire effects within the Rim fire—Relative importance of local climate, fire weather, topography, and forest structure | V. R. Kane, C. A. Cansler, N. A. Povak, J. T. Kane, R. J. McGaughey, J. A. Lutz, D. J. Churchill, M. P. North | 2015 | Kane, V.R., Cansler, C.A., Povak, N.A., Kane, J.T., McGaughey, R.J., Lutz, J.A., Churchill, D.J., and North, M.P., 2015, Mixed severity fire effects within the Rim fire—Relative importance of local climate, fire weather, topography, and forest structure: Forest Ecology and Management, v. 358, p. 62–79, at https://doi.org/10.1016/j.foreco.2015.09.001. |
First-entry wildfires can create opening and tree clump patterns characteristic of resilient forests | V. R. Kane, B. N. Bartl-Geller, M. P. North, J. T. Kane, J. M. Lydersen, S. M. A. Jeronimo, B. M. Collins, L. Monika Moskal | 2019 | Kane, V.R., Bartl-Geller, B.N., North, M.P., Kane, J.T., Lydersen, J.M., Jeronimo, S.M.A., Collins, B.M., and Monika Moskal, L., 2019, First-entry wildfires can create opening and tree clump patterns characteristic of resilient forests: Forest Ecology and Management, v. 454, article 117659, at https://doi.org/10.1016/j.foreco.2019.117659. |
Increasing wildfire impacts on snowpack in the western U.S. | S. K. Kampf, D. McGrath, M. G. Sears, S. R. Fassnacht, L. Kiewiet, J. C. Hammond | 2022 | Kampf, S.K., McGrath, D., Sears, M.G., Fassnacht, S.R., Kiewiet, L., and Hammond, J.C., 2022, Increasing wildfire impacts on snowpack in the western U.S.: Proceedings of the National Academy of Sciences, v. 119, no. 39, article e2200333119, at https://doi.org/10.1073/pnas.2200333119. |
PEMIP—Post-fire erosion model inter-comparison project | S. K. Kampf, B. M. Gannon, C. Wilson, F. Saavedra, M. E. Miller, A. Heldmyer, B. Livneh, P. Nelson, L. MacDonald | 2020 | Kampf, S.K., Gannon, B.M., Wilson, C., Saavedra, F., Miller, M.E., Heldmyer, A., Livneh, B., Nelson, P., and MacDonald, L., 2020, PEMIP—Post-fire erosion model inter-comparison project: Journal of Environmental Management, v. 268, article 110704, at https://doi.org/10.1016/j.jenvman.2020.110704. |
Pathways framework identifies wildfire impacts on agriculture | L. Kabeshita, L. L. Sloat, E. V. Fischer, S. Kampf, S. Magzamen, C. Schultz, M. J. Wilkins, E. Kinnebrew, N. D. Mueller | 2023 | Kabeshita, L., Sloat, L.L., Fischer, E.V., Kampf, S., Magzamen, S., Schultz, C., Wilkins, M.J., Kinnebrew, E., and Mueller, N.D., 2023, Pathways framework identifies wildfire impacts on agriculture: Nature Food, v. 4, p. 664–672, at https://doi.org/10.1038/s43016-023-00803-z. |
Evaluation of spectral indices for mapping burned areas using unsupervised classification in different ecosystems using spectral indices from Sentinel-2 images | J. A. da Silva Júnior, A. da Penha Pacheco | 2023 | da Silva Júnior, J.A., and da Penha Pacheco, A., 2023, Evaluation of spectral indices for mapping burned areas using unsupervised classification in different ecosystems using spectral indices from Sentinel-2 images: Revista Brasileira de Cartografia, v. 75, at https://doi.org/10.14393/RBCV75N0A-68307. |
Wildfire impacts on the persistent suspended sediment dynamics of the Ventura River, California | N. Jumps, A. B. Gray, J. J. Guilinger, W. C. Cowger | 2022 | Jumps, N., Gray, A.B., Guilinger, J.J., and Cowger, W.C., 2022, Wildfire impacts on the persistent suspended sediment dynamics of the Ventura River, California: Journal of Hydrology—Regional Studies, v. 41, article 101096, at https://doi.org/10.1016/j.ejrh.2022.101096. |
Rapid growth of large forest fires drives the exponential response of annual forest?fire area to aridity in the western United States | C. S. Juang, A. P. Williams, J. T. Abatzoglou, J. K. Balch, M. D. Hurteau, M. A. Moritz | 2022 | Juang, C.S., Williams, A.P., Abatzoglou, J.T., Balch, J.K., Hurteau, M.D., and Moritz, M.A., 2022, Rapid growth of large forest fires drives the exponential response of annual forest?fire area to aridity in the western United States: Geophysical Research Letters, v. 49, no. 5, article e2021GL097131, at https://doi.org/10.1029/2021gl097131. |
Spatiotemporal prediction of wildfire size extremes with Bayesian finite sample maxima | M. B. Joseph, M. W. Rossi, N. P. Mietkiewicz, A. L. Mahood, M. E. Cattau, L. A. St. Denis, R. C. Nagy, V. Iglesias, J. T. Abatzoglou, J. K. Balch | 2019 | Joseph, M.B., Rossi, M.W., Mietkiewicz, N.P., Mahood, A.L., Cattau, M.E., St. Denis, L.A., Nagy, R.C., Iglesias, V., Abatzoglou, J.T., and Balch, J.K., 2019, Spatiotemporal prediction of wildfire size extremes with Bayesian finite sample maxima: Ecological Applications, v. 29, no. 6, article e01898, at https://doi.org/10.1002/eap.1898. |
Beyond inventories—Emergence of a new era in rangeland monitoring | M. O. Jones, D. E. Naugle, D. Twidwell, D. R. Uden, J. D. Maestas, B. W. Allred | 2020 | Jones, M.O., Naugle, D.E., Twidwell, D., Uden, D.R., Maestas, J.D., and Allred, B.W., 2020, Beyond inventories—Emergence of a new era in rangeland monitoring: Rangeland Ecology & Management, v. 73, no. 5, p. 577–583, at https://doi.org/10.1016/j.rama.2020.06.009. |
Satellite microwave detection of boreal forest recovery from the extreme 2004 wildfires in Alaska and Canada | M. O. Jones, J. S. Kimball, L. A. Jones | 2013 | Jones, M.O., Kimball, J.S., and Jones, L.A., 2013, Satellite microwave detection of boreal forest recovery from the extreme 2004 wildfires in Alaska and Canada: Global Change Biology, v. 19, no. 10, p. 3111–3122, at https://doi.org/10.1111/gcb.12288. |
Mapping wildfire jurisdictional complexity reveals opportunities for regional co-management | K. Jones, J. Vukomanovic, B. Nowell, S. McGovern | 2024 | Jones, K., Vukomanovic, J., Nowell, B., and McGovern, S., 2024, Mapping wildfire jurisdictional complexity reveals opportunities for regional co-management: Global Environmental Change, v. 84, article 102804, at https://doi.org/10.1016/j.gloenvcha.2024.102804. |
The American West as a social-ecological region—Drivers, dynamics and implications for nested social-ecological systems | K. Jones, J. Abrams, R. T. Belote, B. J. Beltran, J. Brandt, N. Carter, A. J. Castro, B. C. Chaffin, A. L. Metcalf, G. Roesch-McNally, K. E. Wallen, M. A. Williamson | 2019 | Jones, K., Abrams, J., Belote, R.T., Beltran, B.J., Brandt, J., Carter, N., Castro, A.J., Chaffin, B.C., Metcalf, A.L., et al., 2019, The American West as a social-ecological region—Drivers, dynamics and implications for nested social-ecological systems: Environmental Research Letters, v. 14, no. 11, article 115008, at https://doi.org/10.1088/1748-9326/ab4562. |
Spatial and temporal dynamics of Mexican spotted owl habitat in the southwestern US | G. M. Jones, A. J. Shirk, Z. Yang, R. J. Davis, J. L. Ganey, R. J. Gutiérrez, S. P. Healey, S. J. Hedwall, S. J. Hoagland, R. Maes, K. Malcolm, K. S. McKelvey, J. S. Sanderlin, M. K. Schwartz, M. E. Seamans, H. Y. Wan, S. A. Cushman | 2023 | Jones, G.M., Shirk, A.J., Yang, Z., Davis, R.J., Ganey, J.L., Gutiérrez, R.J., Healey, S.P., Hedwall, S.J., Hoagland, S.J., et al., 2023, Spatial and temporal dynamics of Mexican spotted owl habitat in the southwestern US: Landscape Ecology, v. 38, p. 23–37, at https://doi.org/10.1007/s10980-022-01418-8. |
Habitat selection by spotted owls after a megafire reflects their adaptation to historical frequent-fire regimes | G. M. Jones, H. A. Kramer, S. A. Whitmore, W. J. Berigan, D. J. Tempel, C. M. Wood, B. K. Hobart, T. Erker, F. A. Atuo, N. F. Pietrunti, R. Kelsey, R. J. Gutiérrez, M. Z. Peery | 2020 | Jones, G.M., Kramer, H.A., Whitmore, S.A., Berigan, W.J., Tempel, D.J., Wood, C.M., Hobart, B.K., Erker, T., Atuo, F.A., et al., 2020, Habitat selection by spotted owls after a megafire reflects their adaptation to historical frequent-fire regimes: Landscape Ecology, v. 35, no. 5, p. 1199–1213, at https://doi.org/10.1007/s10980-020-01010-y. |
Megafire causes persistent loss of an old?forest species | G. M. Jones, H. A. Kramer, W. J. Berigan, S. A. Whitmore, R. J. Gutiérrez, M. Z. Peery | 2021 | Jones, G.M., Kramer, H.A., Berigan, W.J., Whitmore, S.A., Gutiérrez, R.J., and Peery, M.Z., 2021, Megafire causes persistent loss of an old?forest species: Animal Conservation, v. 24, no. 6, p. 925–936, at https://doi.org/10.1111/acv.12697. |
Extreme wildfire supersedes long-term fuel treatment influences on fuel and vegetation in chaparral ecosystems of northern California, USA | A. M. Jones, J. M. Kane, E. A. Engber, C. A. Martorano, J. Gibson | 2023 | Jones, A.M., Kane, J.M., Engber, E.A., Martorano, C.A., and Gibson, J., 2023, Extreme wildfire supersedes long-term fuel treatment influences on fuel and vegetation in chaparral ecosystems of northern California, USA: Fire Ecology, v. 19, no. 1, article 28, at https://doi.org/10.1186/s42408-023-00186-3. |
Severe Fire Danger Index—A forecastable metric to inform firefighter and community wildfire risk management | W. M. Jolly, P. H. Freeborn, W. G. Page, B. W. Butler | 2019 | Jolly, W.M., Freeborn, P.H., Page, W.G., and Butler, B.W., 2019, Severe Fire Danger Index—A forecastable metric to inform firefighter and community wildfire risk management: Fire, v. 2, no. 3, article 47, at https://doi.org/10.3390/fire2030047. |
Towards improving wildland firefighter situational awareness through daily fire behaviour risk assessments in the US Northern Rockies and northern Great Basin | W. Matt Jolly, P. H. Freeborn | 2017 | Matt Jolly, W., and Freeborn, P.H., 2017, Towards improving wildland firefighter situational awareness through daily fire behaviour risk assessments in the US Northern Rockies and northern Great Basin: International Journal of Wildland Fire, v. 26, no. 7, p. 574–586, at https://doi.org/10.1071/WF16153. |
Does conserving roadless wildland increase wildfire activity in western US national forests? | J. D. Johnston, J. B. Kilbride, G. W. Meigs, C. J. Dunn, R. E. Kennedy | 2021 | Johnston, J.D., Kilbride, J.B., Meigs, G.W., Dunn, C.J., and Kennedy, R.E., 2021, Does conserving roadless wildland increase wildfire activity in western US national forests?: Environmental Research Letters, v. 16, no. 8, article 084040, at https://doi.org/10.1088/1748-9326/ac13ee. |
Tree traits influence response to fire severity in the western Oregon Cascades, USA | J. D. Johnston, C. J. Dunn, M. J. Vernon | 2019 | Johnston, J.D., Dunn, C.J., and Vernon, M.J., 2019, Tree traits influence response to fire severity in the western Oregon Cascades, USA: Forest Ecology and Management, v. 433, p. 690–698, at https://doi.org/10.1016/j.foreco.2018.11.047. |
Historical fire-climate relationships in contrasting interior Pacific Northwest forest types | J. D. Johnston, J. D. Bailey, C. J. Dunn, A. A. Lindsay | 2017 | Johnston, J.D., Bailey, J.D., Dunn, C.J., and Lindsay, A.A., 2017, Historical fire-climate relationships in contrasting interior Pacific Northwest forest types: Fire Ecology, v. 13, no. 2, p. 18–36, at https://doi.org/10.4996/fireecology.130257453. |
Altered vegetation structure from mechanical thinning treatments changed wildfire behaviour in the wildland-urban interface on the 2011 Wallow Fire, Arizona, USA | M. C. Johnson, M. C. Kennedy | 2019 | Johnson, M.C., and Kennedy, M.C., 2019, Altered vegetation structure from mechanical thinning treatments changed wildfire behaviour in the wildland-urban interface on the 2011 Wallow Fire, Arizona, USA: International Journal of Wildland Fire, v. 28, no. 3, p. 216–229, at https://doi.org/10.1071/Wf18062. |
A land cover change detection and classification protocol for updating Alaska NLCD 2001 to 2011 | S. Jin, L. Yang, Z. Zhu, C. Homer | 2017 | Jin, S., Yang, L., Zhu, Z., and Homer, C., 2017, A land cover change detection and classification protocol for updating Alaska NLCD 2001 to 2011: Remote Sensing of Environment, v. 195, p. 44–55, at https://doi.org/10.1016/j.rse.2017.04.021. |
Wildfires correlate with reductions in aboveground tree carbon stocks and sequestration capacity on forest land in the western United States | P. Jiang, M. B. Russell, L. Frelich, C. Babcock, J. E. Smith | 2023 | Jiang, P., Russell, M.B., Frelich, L., Babcock, C., and Smith, J.E., 2023, Wildfires correlate with reductions in aboveground tree carbon stocks and sequestration capacity on forest land in the western United States: Science of the Total Environment, v. 893, article 164832, at https://doi.org/10.1016/j.scitotenv.2023.164832. |
Soil structural degradation during low-severity burns | M. Jian, M. Berli, T. A. Ghezzehei | 2018 | Jian, M., Berli, M., and Ghezzehei, T.A., 2018, Soil structural degradation during low-severity burns: Geophysical Research Letters, v. 45, no. 11, p. 5553–5561, at https://doi.org/10.1029/2018gl078053. |
Estimating aboveground biomass in interior Alaska with Landsat data and field measurements | L. Ji, B. K. Wylie, D. R. Nossov, B. Peterson, M. P. Waldrop, J. W. McFarland, J. Rover, T. N. Hollingsworth | 2012 | Ji, L., Wylie, B.K., Nossov, D.R., Peterson, B., Waldrop, M.P., McFarland, J.W., Rover, J., and Hollingsworth, T.N., 2012, Estimating aboveground biomass in interior Alaska with Landsat data and field measurements: International Journal of Applied Earth Observation and Geoinformation, v. 18, p. 451–461, at https://doi.org/10.1016/j.jag.2012.03.019. |
Spatially explicit estimation of aboveground boreal forest biomass in the Yukon River Basin, Alaska | L. Ji, B. K. Wylie, D. R. N. Brown, B. Peterson, H. D. Alexander, M. C. Mack, J. Rover, M. P. Waldrop, J. W. McFarland, X. Chen, N. J. Pastick | 2015 | Ji, L., Wylie, B.K., Brown, D.R.N., Peterson, B., Alexander, H.D., Mack, M.C., Rover, J., Waldrop, M.P., McFarland, J.W., et al., 2015, Spatially explicit estimation of aboveground boreal forest biomass in the Yukon River Basin, Alaska: International Journal of Remote Sensing, v. 36, no. 4, p. 939–953, at https://doi.org/10.1080/01431161.2015.1004764. |
Temporal greenness trends in stable natural land cover and relationships with climatic variability across the conterminous United States | L. Ji, J. F. Brown | 2022 | Ji, L., and Brown, J.F., 2022, Temporal greenness trends in stable natural land cover and relationships with climatic variability across the conterminous United States: Earth Interactions, v. 26, no. 1, p. 66–83, at https://doi.org/10.1175/ei-d-21-0018.1. |
Forest structure and pattern vary by climate and landform across active-fire landscapes in the montane Sierra Nevada | S. M. A. Jeronimo, V. R. Kane, D. J. Churchill, J. A. Lutz, M. P. North, G. P. Asner, J. F. Franklin | 2019 | Jeronimo, S.M.A., Kane, V.R., Churchill, D.J., Lutz, J.A., North, M.P., Asner, G.P., and Franklin, J.F., 2019, Forest structure and pattern vary by climate and landform across active-fire landscapes in the montane Sierra Nevada: Forest Ecology and Management, v. 437, p. 70–86, at https://doi.org/10.1016/j.foreco.2019.01.033. |
Testing Huston's dynamic equilibrium model along fire and forest productivity gradients using avian monitoring data | W. M. Janousek, V. J. Dreitz | 2020 | Janousek, W.M., and Dreitz, V.J., 2020, Testing Huston's dynamic equilibrium model along fire and forest productivity gradients using avian monitoring data: Diversity and Distributions, v. 26, no. 12, p. 1715–1726, at https://doi.org/10.1111/ddi.13164. |
Biophysical settings that influenced plantation survival during the 2015 wildfires in northern Rocky Mountain moist mixed-conifer forests | T. B. Jain, A. S. Nelson, B. C. Bright, J. C. Byrne, A. T. Hudak | 2021 | Jain, T.B., Nelson, A.S., Bright, B.C., Byrne, J.C., and Hudak, A.T., 2021, Biophysical settings that influenced plantation survival during the 2015 wildfires in northern Rocky Mountain moist mixed-conifer forests: Journal of Forestry, v. 120, no. 1, p. 22–36, at https://doi.org/10.1093/jofore/fvab036. |
The relationship between the polar jet stream and extreme wildfire events in North America | P. Jain, M. Flannigan | 2021 | Jain, P., and Flannigan, M., 2021, The relationship between the polar jet stream and extreme wildfire events in North America: Journal of Climate, v. 34, no. 15, p. 6247–6265, at https://doi.org/10.1175/jcli-d-20-0863.1. |
An unexpected decline in spring atmospheric humidity in the interior southwestern United States and implications for forest fires | T. W. P. Jacobson, R. Seager, A. P. Williams, I. R. Simpson, K. A. McKinnon, H. Liu | 2024 | Jacobson, T.W.P., Seager, R., Williams, A.P., Simpson, I.R., McKinnon, K.A., and Liu, H., 2024, An unexpected decline in spring atmospheric humidity in the interior southwestern United States and implications for forest fires: Journal of Hydrometeorology, v. 25, no. 3, p. 373–390, at https://doi.org/10.1175/jhm-d-23-0121.1. |
Climate dynamics preceding summer forest fires in California and the extreme case of 2018 | T. W. P. Jacobson, R. Seager, A. P. Williams, N. Henderson | 2022 | Jacobson, T.W.P., Seager, R., Williams, A.P., and Henderson, N., 2022, Climate dynamics preceding summer forest fires in California and the extreme case of 2018: Journal of Applied Meteorology and Climatology, v. 61, no. 8, p. 989–1002, at https://doi.org/10.1175/JAMC-D-21-0198.1. |
Comparing social constructions of wildfire risk across media, government, and participatory discourse in a Colorado fireshed | M. Jacobson, H. Smith, H. R. Huber-Stearns, E. J. Davis, A. S. Cheng, A. Deak | 2022 | Jacobson, M., Smith, H., Huber-Stearns, H.R., Davis, E.J., Cheng, A.S., and Deak, A., 2022, Comparing social constructions of wildfire risk across media, government, and participatory discourse in a Colorado fireshed: Journal of Risk Research, v. 25, no. 6, p. 697–714, at https://doi.org/10.1080/13669877.2021.1962954. |
Climate, fire regime, geomorphology, and conspecifics influence the spatial distribution of Chinook Salmon Redds | G. R. Jacobs, R. F. Thurow, J. M. Buffington, D. J. Isaak, S. J. Wenger | 2021 | Jacobs, G.R., Thurow, R.F., Buffington, J.M., Isaak, D.J., and Wenger, S.J., 2021, Climate, fire regime, geomorphology, and conspecifics influence the spatial distribution of Chinook Salmon Redds: Transactions of the American Fisheries Society, v. 150, no. 1, p. 8–23, at https://doi.org/10.1002/tafs.10270. |
Comparing geography and severity of managed wildfires in California and the southwest USA before and after the implementation of the 2009 Policy Guidance | J. M. Iniguez, A. M. Evans, S. Dadashi, J. D. Young, M. D. Meyer, A. E. Thode, S. J. Hedwall, S. M. McCaffrey, S. D. Fillmore, R. Bean | 2022 | Iniguez, J.M., Evans, A.M., Dadashi, S., Young, J.D., Meyer, M.D., Thode, A.E., Hedwall, S.J., McCaffrey, S.M., Fillmore, S.D., and Bean, R., 2022, Comparing geography and severity of managed wildfires in California and the southwest USA before and after the implementation of the 2009 Policy Guidance: Forests, v. 13, no. 5, article 793, at https://doi.org/10.3390/f13050793. |
Viewscape change highlights shifting drivers of exurban development over time | N. C. Inglis, J. Vukomanovic, A. Petrasova, R. K. Meentemeyer | 2023 | Inglis, N.C., Vukomanovic, J., Petrasova, A., and Meentemeyer, R.K., 2023, Viewscape change highlights shifting drivers of exurban development over time: Landscape and Urban Planning, v. 238, article 104833, at https://doi.org/10.1016/j.landurbplan.2023.104833. |
U.S. fires became larger, more frequent, and more widespread in the 2000s | V. Iglesias, J. K. Balch, W. R. Travis | 2022 | Iglesias, V., Balch, J.K., and Travis, W.R., 2022, U.S. fires became larger, more frequent, and more widespread in the 2000s: Science Advances, v. 8, no. 11, article eabc0020, at https://doi.org/10.1126/sciadv.abc0020. |
Effects of vegetation disturbance by fire on channel initiation thresholds | K. D. Hyde, A. C. Wilcox, K. Jencso, S. Woods | 2014 | Hyde, K.D., Wilcox, A.C., Jencso, K., and Woods, S., 2014, Effects of vegetation disturbance by fire on channel initiation thresholds: Geomorphology, v. 214, p. 84–96, at https://doi.org/10.1016/j.geomorph.2014.03.013. |
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Comparing modeled emissions from wildfire and prescribed burning of post-thinning fuel—A case study of the 2016 Pioneer Fire | J. Hyde, E. K. Strand | 2019 | Hyde, J., and Strand, E.K., 2019, Comparing modeled emissions from wildfire and prescribed burning of post-thinning fuel—A case study of the 2016 Pioneer Fire: Fire, v. 2, no. 2, article 22, at https://doi.org/10.3390/fire2020022. |
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A remote sensing-based approach to estimating the fire spread rate parameter for individual burn patch extraction | M. Humber, M. Zubkova, L. Giglio | 2022 | Humber, M., Zubkova, M., and Giglio, L., 2022, A remote sensing-based approach to estimating the fire spread rate parameter for individual burn patch extraction: International Journal of Remote Sensing, v. 43, no. 2, p. 649–673, at https://doi.org/10.1080/01431161.2022.2027544. |
Efficacy of resource objective wildfires for restoration of ponderosa pine (Pinus ponderosa) forests in northern Arizona | D. W. Huffman, A. J. Sánchez Meador, M. T. Stoddard, J. E. Crouse, J. P. Roccaforte | 2017 | Huffman, D.W., Sánchez Meador, A.J., Stoddard, M.T., Crouse, J.E., and Roccaforte, J.P., 2017, Efficacy of resource objective wildfires for restoration of ponderosa pine (Pinus ponderosa) forests in northern Arizona: Forest Ecology and Management, v. 389, p. 395–403, at https://doi.org/10.1016/j.foreco.2016.12.036. |
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Charcoal reflectance suggests heating duration and fuel moisture affected burn severity in four Alaskan tundra wildfires | V. A. Hudspith, C. M. Belcher, J. Barnes, C. B. Dash, R. Kelly, F. S. Hu | 2017 | Hudspith, V.A., Belcher, C.M., Barnes, J., Dash, C.B., Kelly, R., and Hu, F.S., 2017, Charcoal reflectance suggests heating duration and fuel moisture affected burn severity in four Alaskan tundra wildfires: International Journal of Wildland Fire, v. 26, no. 4, p. 306–316, at https://doi.org/10.1071/Wf16177. |
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Evaluation and improvement of the Community Land Model (CLM4) in Oregon forests | T. W. Hudiburg, B. E. Law, P. E. Thornton | 2013 | Hudiburg, T.W., Law, B.E., and Thornton, P.E., 2013, Evaluation and improvement of the Community Land Model (CLM4) in Oregon forests: Biogeosciences, v. 10, no. 1, p. 453–470, at https://doi.org/10.5194/bg-10-453-2013. |
Updating land cover automatically based on change detection using satellite images—Case study of national forests in southern California | S. L. Huang, C. Ramirez, K. Kennedy, J. Mallory, J. L. Wang, C. Chu | 2017 | Huang, S.L., Ramirez, C., Kennedy, K., Mallory, J., Wang, J.L., and Chu, C., 2017, Updating land cover automatically based on change detection using satellite images—Case study of national forests in southern California: GIScience & Remote Sensing, v. 54, no. 4, p. 495–514, at https://doi.org/10.1080/15481603.2017.1286727. |
Projecting the spatiotemporal carbon dynamics of the Greater Yellowstone Ecosystem from 2006 to 2050 | S. Huang, S. Liu, J. Liu, D. Dahal, C. Young, B. Davis, T. L. Sohl, T. J. Hawbaker, B. Sleeter, Z. Zhu | 2015 | Huang, S., Liu, S., Liu, J., Dahal, D., Young, C., Davis, B., Sohl, T.L., Hawbaker, T.J., Sleeter, B., and Zhu, Z., 2015, Projecting the spatiotemporal carbon dynamics of the Greater Yellowstone Ecosystem from 2006 to 2050: Carbon Balance and Management, v. 10, no. 1, article 7, at https://doi.org/10.1186/s13021-015-0017-6. |
Modeling spatially explicit fire impact on gross primary production in interior Alaska using satellite images coupled with eddy covariance | S. Huang, H. Liu, D. Dahal, S. Jin, L. R. Welp, J. Liu, S. Liu | 2013 | Huang, S., Liu, H., Dahal, D., Jin, S., Welp, L.R., Liu, J., and Liu, S., 2013, Modeling spatially explicit fire impact on gross primary production in interior Alaska using satellite images coupled with eddy covariance: Remote Sensing of Environment, v. 135, p. 178–188, at https://doi.org/10.1016/j.rse.2013.04.003. |
Reconstructing satellite images to quantify spatially explicit land surface change caused by fires and succession—A demonstration in the Yukon River Basin of interior Alaska | S. Huang, S. Jin, D. Dahal, X. Chen, C. Young, H. Liu, S. Liu | 2013 | Huang, S., Jin, S., Dahal, D., Chen, X., Young, C., Liu, H., and Liu, S., 2013, Reconstructing satellite images to quantify spatially explicit land surface change caused by fires and succession—A demonstration in the Yukon River Basin of interior Alaska: ISPRS Journal of Photogrammetry and Remote Sensing, v. 79, p. 94–105, at https://doi.org/10.1016/j.isprsjprs.2013.02.010. |
The economic value of selling carbon credits from restored forests—A case study from the Navajo nation's tribal forests | C. H. Huang, C. Sorensen | 2011 | Huang, C.H., and Sorensen, C., 2011, The economic value of selling carbon credits from restored forests—A case study from the Navajo nation's tribal forests: Western Journal of Applied Forestry, v. 26, no. 1, p. 37–45, at https://doi.org/10.1093/wjaf/26.1.37. |
Development of time series stacks of Landsat images for reconstructing forest disturbance history | C. Huang, S. N. Goward, J. G. Masek, F. Gao, E. F. Vermote, N. Thomas, K. Schleeweis, R. E. Kennedy, Z. Zhu, J. C. Eidenshink, J. R. G. Townshend | 2009 | Huang, C., Goward, S.N., Masek, J.G., Gao, F., Vermote, E.F., Thomas, N., Schleeweis, K., Kennedy, R.E., Zhu, Z., et al., 2009, Development of time series stacks of Landsat images for reconstructing forest disturbance history: International Journal of Digital Earth, v. 2, no. 3, p. 195–218, at https://doi.org/10.1080/17538940902801614. |
Large-scale burn severity mapping in multispectral imagery using deep semantic segmentation models | X. Hu, P. Zhang, Y. Ban | 2023 | Hu, X., Zhang, P., and Ban, Y., 2023, Large-scale burn severity mapping in multispectral imagery using deep semantic segmentation models: ISPRS Journal of Photogrammetry and Remote Sensing, v. 196, p. 228–240, at https://doi.org/10.1016/j.isprsjprs.2022.12.026. |
Comparing Sentinel-2 and Landsat 8 for burn severity mapping in western North America | A. A. Howe, S. A. Parks, B. J. Harvey, S. J. Saberi, J. A. Lutz, L. L. Yocom | 2022 | Howe, A.A., Parks, S.A., Harvey, B.J., Saberi, S.J., Lutz, J.A., and Yocom, L.L., 2022, Comparing Sentinel-2 and Landsat 8 for burn severity mapping in western North America: Remote Sensing, v. 14, no. 20, article 5249, at https://doi.org/10.3390/rs14205249. |
Can Siberian alder N-fixation offset N-loss after severe fire? Quantifying post-fire Siberian alder distribution, growth, and N-fixation in boreal Alaska | B. Houseman, R. Ruess, T. Hollingsworth, D. Verbyla | 2020 | Houseman, B., Ruess, R., Hollingsworth, T., and Verbyla, D., 2020, Can Siberian alder N-fixation offset N-loss after severe fire? Quantifying post-fire Siberian alder distribution, growth, and N-fixation in boreal Alaska: PLoS ONE, v. 15, no. 9, article e0238004, at https://doi.org/10.1371/journal.pone.0238004. |
Interactive effects of wildfire, forest management, and isolation on amphibian and parasite abundance | B. R. Hossack, W. H. Lowe, R. K. Honeycutt, S. A. Parks, P. S. Corn | 2013 | Hossack, B.R., Lowe, W.H., Honeycutt, R.K., Parks, S.A., and Corn, P.S., 2013, Interactive effects of wildfire, forest management, and isolation on amphibian and parasite abundance: Ecological Applications, v. 23, no. 2, p. 479–492, at https://doi.org/10.1890/12-0316.1. |
Rapid increases and time-lagged declines in amphibian occupancy after wildfire | B. R. Hossack, W. H. Lowe, P. S. Corn | 2013 | Hossack, B.R., Lowe, W.H., and Corn, P.S., 2013, Rapid increases and time-lagged declines in amphibian occupancy after wildfire: Conservation Biology, v. 27, no. 1, p. 219–228, at https://doi.org/10.1111/j.1523-1739.2012.01921.x. |
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Germination response to temperature and moisture to predict distributions of the invasive grass red brome and wildfire | K. J. Horn, R. Nettles, S. B. St Clair | 2015 | Horn, K.J., Nettles, R., and St Clair, S.B., 2015, Germination response to temperature and moisture to predict distributions of the invasive grass red brome and wildfire: Biological Invasions, v. 17, no. 6, p. 1849–1857, at https://doi.org/10.1007/s10530-015-0841-3. |
Wildfire and exotic grass invasion alter plant productivity in response to climate variability in the Mojave Desert | K. J. Horn, S. B. St. Clair | 2016 | Horn, K.J., and St. Clair, S.B., 2016, Wildfire and exotic grass invasion alter plant productivity in response to climate variability in the Mojave Desert: Landscape Ecology, v. 32, no. 3, p. 635–646, at https://doi.org/10.1007/s10980-016-0466-7. |
Conterminous United States land cover change patterns 2001–2016 from the 2016 National Land Cover Database | C. Homer, J. Dewitz, S. Jin, G. Xian, C. Costello, P. Danielson, L. Gass, M. Funk, J. Wickham, S. Stehman, R. Auch, K. Riitters | 2020 | Homer, C., Dewitz, J., Jin, S., Xian, G., Costello, C., Danielson, P., Gass, L., Funk, M., Wickham, J., et al., 2020, Conterminous United States land cover change patterns 2001–2016 from the 2016 National Land Cover Database: ISPRS Journal of Photogrammetry and Remote Sensing, v. 162, p. 184–199, at https://doi.org/10.1016/j.isprsjprs.2020.02.019. |
Improved fire severity mapping in the North American boreal forest using a hybrid composite method | L. M. Holsinger, S. A. Parks, L. B. Saperstein, R. A. Loehman, E. Whitman, J. Barnes, M. A. Parisien | 2022 | Holsinger, L.M., Parks, S.A., Saperstein, L.B., Loehman, R.A., Whitman, E., Barnes, J., and Parisien, M.A., 2022, Improved fire severity mapping in the North American boreal forest using a hybrid composite method: Remote Sensing in Ecology and Conservation, v. 8, no. 2, p. 222–235, at https://doi.org/10.1002/rse2.238. |
Weather, fuels, and topography impede wildland fire spread in western US landscapes | L. Holsinger, S. A. Parks, C. Miller | 2016 | Holsinger, L., Parks, S.A., and Miller, C., 2016, Weather, fuels, and topography impede wildland fire spread in western US landscapes: Forest Ecology and Management, v. 380, p. 59–69, at https://doi.org/10.1016/j.foreco.2016.08.035. |
Wildfire probability estimated from recent climate and fine fuels across the big sagebrush region | M. C. Holdrege, D. R. Schlaepfer, K. A. Palmquist, M. Crist, K. E. Doherty, W. K. Lauenroth, T. E. Remington, K. Riley, K. C. Short, J. C. Tull, L. A. Wiechman, J. B. Bradford | 2024 | Holdrege, M.C., Schlaepfer, D.R., Palmquist, K.A., Crist, M., Doherty, K.E., Lauenroth, W.K., Remington, T.E., Riley, K., Short, K.C., et al., 2024, Wildfire probability estimated from recent climate and fine fuels across the big sagebrush region: Fire Ecology, v. 20, no. 1, article 22, at https://doi.org/10.1186/s42408-024-00252-4. |
Decreasing fire season precipitation increased recent western US forest wildfire activity | Z. A. Holden, A. Swanson, C. H. Luce, W. M. Jolly, M. Maneta, J. W. Oyler, D. A. Warren, R. Parsons, D. Affleck | 2018 | Holden, Z.A., Swanson, A., Luce, C.H., Jolly, W.M., Maneta, M., Oyler, J.W., Warren, D.A., Parsons, R., and Affleck, D., 2018, Decreasing fire season precipitation increased recent western US forest wildfire activity: Proceedings of the National Academy of Sciences of the United States of America, v. 115, no. 36, p. E8349–E8357, at https://doi.org/10.1073/pnas.1802316115. |
A predictive model of burn severity based on 20-year satellite-inferred burn severity data in a large southwestern US wilderness area | Z. A. Holden, P. Morgan, J. S. Evans | 2009 | Holden, Z.A., Morgan, P., and Evans, J.S., 2009, A predictive model of burn severity based on 20-year satellite-inferred burn severity data in a large southwestern US wilderness area: Forest Ecology and Management, v. 258, no. 11, p. 2399–2406, at https://doi.org/10.1016/j.foreco.2009.08.017. |
Wildfire extent and severity correlated with annual streamflow distribution and timing in the Pacific Northwest, USA (1984–2005) | Z. A. Holden, C. H. Luce, M. A. Crimmins, P. Morgan | 2012 | Holden, Z.A., Luce, C.H., Crimmins, M.A., and Morgan, P., 2012, Wildfire extent and severity correlated with annual streamflow distribution and timing in the Pacific Northwest, USA (1984–2005): Ecohydrology, v. 5, no. 5, p. 677–684, at https://doi.org/10.1002/eco.257. |
Fire severity influences the response of soil microbes to a boreal forest fire | S. R. Holden, B. M. Rogers, K. K. Treseder, J. T. Randerson | 2016 | Holden, S.R., Rogers, B.M., Treseder, K.K., and Randerson, J.T., 2016, Fire severity influences the response of soil microbes to a boreal forest fire: Environmental Research Letters, v. 11, no. 3, article 035004, at https://doi.org/10.1088/1748-9326/11/3/035004. |
Changes in severity distribution after subsequent fires on the north rim of Grand Canyon National Park, Arizona, USA | V. Hoff, C. C. Teske, J. P. Riddering, L. P. Queen, E. G. Gdula, W. A. Bunn | 2014 | Hoff, V., Teske, C.C., Riddering, J.P., Queen, L.P., Gdula, E.G., and Bunn, W.A., 2014, Changes in severity distribution after subsequent fires on the north rim of Grand Canyon National Park, Arizona, USA: Fire Ecology, v. 10, no. 2, p. 48–63, at https://doi.org/10.4996/fireecology.1002048. |
Assessing the relationship between forest structure and fire severity on the north rim of the Grand Canyon | V. Hoff, E. Rowell, C. Teske, L. Queen, T. Wallace | 2019 | Hoff, V., Rowell, E., Teske, C., Queen, L., and Wallace, T., 2019, Assessing the relationship between forest structure and fire severity on the north rim of the Grand Canyon: Fire, v. 2, no. 1, article 10, at https://doi.org/10.3390/fire2010010. |
A short-interval reburn catalyzes departures from historical structure and composition in a mesic mixed-conifer forest | T. J. Hoecker, M. G. Turner | 2022 | Hoecker, T.J., and Turner, M.G., 2022, A short-interval reburn catalyzes departures from historical structure and composition in a mesic mixed-conifer forest: Forest Ecology and Management, v. 504, article 119814, at https://doi.org/10.1016/j.foreco.2021.119814. |
Widespread exposure to altered fire regimes under 2?°C warming is projected to transform conifer forests of the western United States | T. J. Hoecker, S. A. Parks, M. Krosby, S. Z. Dobrowski | 2023 | Hoecker, T.J., Parks, S.A., Krosby, M., and Dobrowski, S.Z., 2023, Widespread exposure to altered fire regimes under 2?°C warming is projected to transform conifer forests of the western United States: Communications Earth & Environment, v. 4, no. 1, article 295, at https://doi.org/10.1038/s43247-023-00954-8. |
Multitemporal LiDAR improves estimates of fire severity in forested landscapes | M. S. Hoe, C. J. Dunn, H. Temesgen | 2018 | Hoe, M.S., Dunn, C.J., and Temesgen, H., 2018, Multitemporal LiDAR improves estimates of fire severity in forested landscapes: International Journal of Wildland Fire, v. 27, no. 9, p. 581–594, at https://doi.org/10.1071/Wf17141. |
Stable isotopes reveal unexpected relationships between fire history and the diet of spotted owls | B. K. Hobart, H. A. Kramer, G. M. Jones, B. P. Dotters, S. A. Whitmore, J. J. Keane, M. Z. Peery | 2021 | Hobart, B.K., Kramer, H.A., Jones, G.M., Dotters, B.P., Whitmore, S.A., Keane, J.J., and Peery, M.Z., 2021, Stable isotopes reveal unexpected relationships between fire history and the diet of spotted owls: IBIS, v. 163, no. 1, p. 253–259, at https://doi.org/10.1111/ibi.12832. |
Hydrological and meteorological controls on large wildfire ignition and burned area in northern California during 2017–2020 | Y. Hiraga, M. L. Kavvas | 2021 | Hiraga, Y., and Kavvas, M.L., 2021, Hydrological and meteorological controls on large wildfire ignition and burned area in northern California during 2017–2020: Fire, v. 4, no. 4, article 90, at https://doi.org/10.3390/fire4040090. |
Rocky Mountain subalpine forests now burning more than any time in recent millennia | P. E. Higuera, B. N. Shuman, K. D. Wolf | 2021 | Higuera, P.E., Shuman, B.N., and Wolf, K.D., 2021, Rocky Mountain subalpine forests now burning more than any time in recent millennia: Proceedings of the National Academy of Sciences of the United States of America, v. 118, no. 25, article e2103135118, at https://doi.org/10.1073/pnas.2103135118. |
Shifting social-ecological fire regimes explain increasing structure loss from western wildfires | P. E. Higuera, M. C. Cook, J. K. Balch, E. N. Stavros, A. L. Mahood, L. A. St. Denis | 2023 | Higuera, P.E., Cook, M.C., Balch, J.K., Stavros, E.N., Mahood, A.L., and St. Denis, L.A., 2023, Shifting social-ecological fire regimes explain increasing structure loss from western wildfires: PNAS Nexus, v. 2, article pgad005, at https://doi.org/10.1093/pnasnexus/pgad005/7017542. |
Recent tree mortality in the western United States from bark beetles and forest fires | J. A. Hicke, A. J. H. Meddens, C. A. Kolden | 2016 | Hicke, J.A., Meddens, A.J.H., and Kolden, C.A., 2016, Recent tree mortality in the western United States from bark beetles and forest fires: Forest Science, v. 62, no. 2, p. 141–153, at https://doi.org/10.5849/forsci.15-086. |
Carbon stocks of trees killed by bark beetles and wildfire in the western United States | J. A. Hicke, A. J. H. Meddens, C. D. Allen, C. A. Kolden | 2013 | Hicke, J.A., Meddens, A.J.H., Allen, C.D., and Kolden, C.A., 2013, Carbon stocks of trees killed by bark beetles and wildfire in the western United States: Environmental Research Letters, v. 8, no. 3, article 035032, at https://doi.org/10.1088/1748-9326/8/3/035032. |
Is burn severity related to fire intensity? Observations from landscape scale remote sensing | H. Heward, A. M. S. Smith, D. P. Roy, W. T. Tinkham, C. M. Hoffman, P. Morgan, K. O. Lannom | 2013 | Heward, H., Smith, A.M.S., Roy, D.P., Tinkham, W.T., Hoffman, C.M., Morgan, P., and Lannom, K.O., 2013, Is burn severity related to fire intensity? Observations from landscape scale remote sensing: International Journal of Wildland Fire, v. 22, no. 7, p. 910–918, at https://doi.org/10.1071/WF12087. |
Wildfire burn severity and stream chemistry influence aquatic invertebrate and riparian avian mercury exposure in forested ecosystems | G. Herring, L. B. Tennant, J. J. Willacker, M. Johnson, R. B. Siegel, J. S. Polasik, C. A. Eagles-Smith | 2024 | Herring, G., Tennant, L.B., Willacker, J.J., Johnson, M., Siegel, R.B., Polasik, J.S., and Eagles-Smith, C.A., 2024, Wildfire burn severity and stream chemistry influence aquatic invertebrate and riparian avian mercury exposure in forested ecosystems: Ecotoxicology, v. 33, p. 131–141, at https://doi.org/10.1007/s10646-024-02730-6. |
Assessing the effectiveness of green landscape buffers to reduce fire severity and limit fire spread in California—Case study of golf courses | C. Herbert, V. Butsic | 2022 | Herbert, C., and Butsic, V., 2022, Assessing the effectiveness of green landscape buffers to reduce fire severity and limit fire spread in California—Case study of golf courses: Fire, v. 5, no. 2, article 44, at https://doi.org/10.3390/fire5020044. |
The effects of post-wildfire salvage logging on plant reproductive success and pollination in Symphoricarpos albus, a fire-tolerant shrub | L. J. Heil, L. A. Burkle | 2019 | Heil, L.J., and Burkle, L.A., 2019, The effects of post-wildfire salvage logging on plant reproductive success and pollination in Symphoricarpos albus, a fire-tolerant shrub: Forest Ecology and Management, v. 432, p. 157–163, at https://doi.org/10.1016/j.foreco.2018.09.013. |
Recent post-wildfire salvage logging benefits local and landscape floral and bee communities | L. J. Heil, L. A. Burkle | 2018 | Heil, L.J., and Burkle, L.A., 2018, Recent post-wildfire salvage logging benefits local and landscape floral and bee communities: Forest Ecology and Management, v. 424, p. 267–275, at https://doi.org/10.1016/j.foreco.2018.05.009. |
A framework for simulating map error in ecosystem models | S. P. Healey, S. P. Urbanski, P. L. Patterson, C. Garrard | 2014 | Healey, S.P., Urbanski, S.P., Patterson, P.L., and Garrard, C., 2014, A framework for simulating map error in ecosystem models: Remote Sensing of Environment, v. 150, p. 207–217, at https://doi.org/10.1016/j.rse.2014.04.028. |
Changes in timber haul emissions in the context of shifting forest management and infrastructure | S. P. Healey, J. A. Blackard, T. A. Morgan, D. Loeffler, G. Jones, J. Songster, J. P. Brandt, G. G. Moisen, L. T. DeBlander | 2009 | Healey, S.P., Blackard, J.A., Morgan, T.A., Loeffler, D., Jones, G., Songster, J., Brandt, J.P., Moisen, G.G., and DeBlander, L.T., 2009, Changes in timber haul emissions in the context of shifting forest management and infrastructure: Carbon Balance and Management, v. 4, article 9, at https://doi.org/10.1186/1750-0680-4-9. |
Long-term forest health implications of roadlessness | S. P. Healey | 2020 | Healey, S.P., 2020, Long-term forest health implications of roadlessness: Environmental Research Letters, v. 15, no. 10, article 104023, at https://doi.org/10.1088/1748-9326/aba031. |
Analyzing the effects of land cover change on the water balance for case study watersheds in different forested ecosystems in the USA | N. C. Healey, J. A. Rover | 2022 | Healey, N.C., and Rover, J.A., 2022, Analyzing the effects of land cover change on the water balance for case study watersheds in different forested ecosystems in the USA: Land, v. 11, no. 2, article 316, at https://doi.org/10.3390/land11020316. |
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Tree mortality and structural change following mixed-severity fire in Pseudotsuga forests of Oregon’s western Cascades, USA | C. J. Dunn, J. D. Bailey | 2016 | Dunn, C.J., and Bailey, J.D., 2016, Tree mortality and structural change following mixed-severity fire in Pseudotsuga forests of Oregon’s western Cascades, USA: Forest Ecology and Management, v. 365, p. 107–118, at https://doi.org/10.1016/j.foreco.2016.01.031. |
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Large-scale wildfire reduces population growth in a peripheral population of sage-grouse | I. F. Dudley, P. S. Coates, B. G. Prochazka, S. T. O’Neil, S. Gardner, D. J. Delehanty | 2021 | Dudley, I.F., Coates, P.S., Prochazka, B.G., O’Neil, S.T., Gardner, S., and Delehanty, D.J., 2021, Large-scale wildfire reduces population growth in a peripheral population of sage-grouse: Fire Ecology, v. 17, no. 1, article 15, at https://doi.org/10.1186/s42408-021-00099-z. |
Maladaptive nest?site selection and reduced nest survival in female sage?grouse following wildfire | I. F. Dudley, P. S. Coates, B. G. Prochazka, D. M. Davis, S. C. Gardner, D. J. Delehanty | 2022 | Dudley, I.F., Coates, P.S., Prochazka, B.G., Davis, D.M., Gardner, S.C., and Delehanty, D.J., 2022, Maladaptive nest?site selection and reduced nest survival in female sage?grouse following wildfire: Ecosphere, v. 13, no. 12, article e4282, at https://doi.org/10.1002/ecs2.4282. |
Differential landscape use by forest owls two years after a mixed-severity wildfire | L. S. Duchac, D. B. Lesmeister, K. M. Dugger, R. J. Davis | 2021 | Duchac, L.S., Lesmeister, D.B., Dugger, K.M., and Davis, R.J., 2021, Differential landscape use by forest owls two years after a mixed-severity wildfire: Ecosphere, v. 12, no. 10, article e03770, at https://doi.org/10.1002/ecs2.3770. |
Monitoring annual land use/land cover change in the Tucson metropolitan area with Google Earth Engine (1986–2020) | F. Dubertret, F. M. L. Tourneau, M. L. Villarreal, L. M. Norman | 2022 | Dubertret, F., Tourneau, F.M.L., Villarreal, M.L., and Norman, L.M., 2022, Monitoring annual land use/land cover change in the Tucson metropolitan area with Google Earth Engine (1986–2020): Remote Sensing, v. 14, no. 9, article 2127, at https://doi.org/10.3390/rs14092127. |
Intercomparison of fire size, fuel loading, fuel consumption, and smoke emissions estimates on the 2006 tripod fire, Washington, USA | S. A. Drury, N. S. Larkin, T. T. Strand, S. Huang, S. J. Strenfel, E. M. Banwell, T. E. O'Brien, S. M. Raffuse | 2014 | Drury, S.A., Larkin, N.S., Strand, T.T., Huang, S., Strenfel, S.J., Banwell, E.M., O'Brien, T.E., and Raffuse, S.M., 2014, Intercomparison of fire size, fuel loading, fuel consumption, and smoke emissions estimates on the 2006 tripod fire, Washington, USA: Fire Ecology, v. 10, no. 1, p. 56–83, at https://doi.org/10.4996/fireecology.1001056. |
Assessing landscape change and processes of recurrence, replacement, and recovery in the southeastern coastal plains, USA | M. A. Drummond, M. P. Stier, R. F. Auch, J. L. Taylor, G. E. Griffith, J. L. Riegle, D. J. Hester, C. E. Soulard, J. L. McBeth | 2015 | Drummond, M.A., Stier, M.P., Auch, R.F., Taylor, J.L., Griffith, G.E., Riegle, J.L., Hester, D.J., Soulard, C.E., and McBeth, J.L., 2015, Assessing landscape change and processes of recurrence, replacement, and recovery in the southeastern coastal plains, USA: Environmental Management, v. 56, no. 5, p. 1252–71, at https://doi.org/10.1007/s00267-015-0574-1. |
Understanding recurrent land use processes and long-term transitions in the dynamic south-central United States, c. 1800 to 2006 | M. A. Drummond, G. E. Griffith, R. F. Auch, M. P. Stier, J. L. Taylor, D. J. Hester, J. L. Riegle, J. L. McBeth | 2017 | Drummond, M.A., Griffith, G.E., Auch, R.F., Stier, M.P., Taylor, J.L., Hester, D.J., Riegle, J.L., and McBeth, J.L., 2017, Understanding recurrent land use processes and long-term transitions in the dynamic south-central United States, c. 1800 to 2006: Land Use Policy, v. 68, p. 345–354, at https://doi.org/10.1016/j.landusepol.2017.07.061. |
Where and why do conifer forests persist in refugia through multiple fire events? | W. M. Downing, G. W. Meigs, M. J. Gregory, M. A. Krawchuk | 2021 | Downing, W.M., Meigs, G.W., Gregory, M.J., and Krawchuk, M.A., 2021, Where and why do conifer forests persist in refugia through multiple fire events?: Global Change Biology, v. 27, no. 15, p. 3642–3656, at https://doi.org/10.1111/gcb.15655. |
Influence of fire refugia spatial pattern on post-fire forest recovery in Oregon's Blue Mountains | W. M. Downing, M. A. Krawchuk, G. W. Meigs, S. L. Haire, J. D. Coop, R. B. Walker, E. Whitman, G. Chong, C. Miller | 2019 | Downing, W.M., Krawchuk, M.A., Meigs, G.W., Haire, S.L., Coop, J.D., Walker, R.B., Whitman, E., Chong, G., and Miller, C., 2019, Influence of fire refugia spatial pattern on post-fire forest recovery in Oregon's Blue Mountains: Landscape Ecology, v. 34, no. 4, p. 771–792, at https://doi.org/10.1007/s10980-019-00802-1. |
How do plant communities differ between fire refugia and fire?generated early?seral vegetation? | W. M. Downing, M. A. Krawchuk, J. D. Coop, G. W. Meigs, S. L. Haire, R. B. Walker, E. Whitman, G. Chong, C. Miller, C. Tortorelli, S. Roxburgh | 2019 | Downing, W.M., Krawchuk, M.A., Coop, J.D., Meigs, G.W., Haire, S.L., Walker, R.B., Whitman, E., Chong, G., Miller, C., et al., 2019, How do plant communities differ between fire refugia and fire?generated early?seral vegetation?: Journal of Vegetation Science, v. 31, no. 1, p. 26–39, at https://doi.org/10.1111/jvs.12814. |
Employing Copernicus Land Service and Sentinel-2 satellite mission data to assess the spatial dynamics and distribution of the extreme forest fires of 2023 in Greece | A. Dosiou, I. Athinelis, E. Katris, M. Vassalou, A. Kyrkos, P. Krassakis, I. Parcharidis | 2024 | Dosiou, A., Athinelis, I., Katris, E., Vassalou, M., Kyrkos, A., Krassakis, P., and Parcharidis, I., 2024, Employing Copernicus Land Service and Sentinel-2 satellite mission data to assess the spatial dynamics and distribution of the extreme forest fires of 2023 in Greece: Fire, v. 7, no. 1, article 20, at https://doi.org/10.3390/fire7010020. |
Land-use type as a driver of large wildfire occurrence in the U.S. Great Plains | V. M. Donovan, C. L. Wonkka, D. A. Wedin, D. Twidwell | 2020 | Donovan, V.M., Wonkka, C.L., Wedin, D.A., and Twidwell, D., 2020, Land-use type as a driver of large wildfire occurrence in the U.S. Great Plains: Remote Sensing, v. 12, no. 11, article 1869, at https://doi.org/10.3390/rs12111869. |
Surging wildfire activity in a grassland biome | V. M. Donovan, C. L. Wonkka, D. Twidwell | 2017 | Donovan, V.M., Wonkka, C.L., and Twidwell, D., 2017, Surging wildfire activity in a grassland biome: Geophysical Research Letters, v. 44, no. 12, p. 5986–5993, at https://doi.org/10.1002/2017gl072901. |
The influence of wildfire on invasive plant abundance and spatial structure in eastern ponderosa pine savanna | V. M. Donovan, C. L. Wonkka, C. P. Roberts, D. A. Wedin, D. A. McGranahan, D. Twidwell | 2023 | Donovan, V.M., Wonkka, C.L., Roberts, C.P., Wedin, D.A., McGranahan, D.A., and Twidwell, D., 2023, The influence of wildfire on invasive plant abundance and spatial structure in eastern ponderosa pine savanna: Plant Ecology, v. 224, p. 987–999, at https://doi.org/10.1007/s11258-023-01355-9. |
Resilience to large, “catastrophic” wildfires in North America's grassland biome | V. M. Donovan, D. Twidwell, D. R. Uden, T. Tadesse, B. D. Wardlow, C. H. Bielski, M. O. Jones, B. W. Allred, D. E. Naugle, C. R. Allen | 2020 | Donovan, V.M., Twidwell, D., Uden, D.R., Tadesse, T., Wardlow, B.D., Bielski, C.H., Jones, M.O., Allred, B.W., Naugle, D.E., and Allen, C.R., 2020, Resilience to large, “catastrophic” wildfires in North America's grassland biome: Earth's Future, v. 8, no. 7, article e2020EF001487, at https://doi.org/10.1029/2020EF001487. |
Ponderosa pine regeneration, wildland fuels management, and habitat conservation—Identifying trade-offs following wildfire | V. M. Donovan, C. P. Roberts, C. L. Wonkka, D. A. Wedin, D. Twidwell | 2019 | Donovan, V.M., Roberts, C.P., Wonkka, C.L., Wedin, D.A., and Twidwell, D., 2019, Ponderosa pine regeneration, wildland fuels management, and habitat conservation—Identifying trade-offs following wildfire: Forests, v. 10, no. 3, article 286, at https://doi.org/10.3390/f10030286. |
Collapse, reorganization, and regime identity—Breaking down past management paradigms in a forest-grassland ecotone | V. M. Donovan, C. P. Roberts, C. L. Wonkka, D. R. Uden, D. G. Angeler, C. R. Allen, D. A. Wedin, R. A. Drijber, D. Twidwell | 2021 | Donovan, V.M., Roberts, C.P., Wonkka, C.L., Uden, D.R., Angeler, D.G., Allen, C.R., Wedin, D.A., Drijber, R.A., and Twidwell, D., 2021, Collapse, reorganization, and regime identity—Breaking down past management paradigms in a forest-grassland ecotone: Ecology and Society, v. 26, no. 2, article 27, at https://doi.org/10.5751/es-12340-260227. |
Targeted grazing and mechanical thinning enhance forest stand resilience under a narrow range of wildfire scenarios | V. M. Donovan, C. P. Roberts, D. T. Fogarty, D. A. Wedin, D. Twidwell | 2022 | Donovan, V.M., Roberts, C.P., Fogarty, D.T., Wedin, D.A., and Twidwell, D., 2022, Targeted grazing and mechanical thinning enhance forest stand resilience under a narrow range of wildfire scenarios: Ecosphere, v. 13, no. 5, article e4061, at https://doi.org/10.1002/ecs2.4061. |
Relationships between wildfire burn severity, cavity-nesting bird assemblages, and habitat in an eastern ponderosa pine forest | V. M. Donovan, E. C. Keele, C. P. Roberts, S. M. Nodskov, C. L. Wonkka, C. R. Allen, L. A. Powell, D. A. Wedin, D. G. Angeler, D. Twidwell | 2019 | Donovan, V.M., Keele, E.C., Roberts, C.P., Nodskov, S.M., Wonkka, C.L., Allen, C.R., Powell, L.A., Wedin, D.A., Angeler, D.G., and Twidwell, D., 2019, Relationships between wildfire burn severity, cavity-nesting bird assemblages, and habitat in an eastern ponderosa pine forest: The American Midland Naturalist, v. 181, no. 1, p. 1–17, at https://doi.org/10.1674/0003-0031-181.1.1. |
Fire-driven landscape heterogeneity shapes habitat selection of bighorn sheep | V. M. Donovan, S. P. H. Dwinnell, J. L. Beck, C. P. Roberts, J. G. Clapp, G. S. Hiatt, K. L. Monteith, D. Twidwell | 2021 | Donovan, V.M., Dwinnell, S.P.H., Beck, J.L., Roberts, C.P., Clapp, J.G., Hiatt, G.S., Monteith, K.L., and Twidwell, D., 2021, Fire-driven landscape heterogeneity shapes habitat selection of bighorn sheep: Journal of Mammalogy, v. 102, no. 3, p. 757–771, at https://doi.org/10.1093/jmammal/gyab035. |
Increasing large wildfire in the eastern United States | V. M. Donovan, R. Crandall, J. Fill, C. L. Wonkka | 2023 | Donovan, V.M., Crandall, R., Fill, J., and Wonkka, C.L., 2023, Increasing large wildfire in the eastern United States: Geophysical Research Letters, v. 50, no. 24, article e2023GL107051, at https://doi.org/10.1029/2023GL107051. |
Declining pronghorn (Antilocapra americana) population productivity caused by woody encroachment and oil and gas development | V. M. Donovan, J. L. Beck, C. L. Wonkka, C. P. Roberts, C. R. Allen, D. Twidwell | 2024 | Donovan, V.M., Beck, J.L., Wonkka, C.L., Roberts, C.P., Allen, C.R., and Twidwell, D., 2024, Declining pronghorn (Antilocapra americana) population productivity caused by woody encroachment and oil and gas development: Global Ecology and Conservation, v. 50, article e02848, at https://doi.org/10.1016/j.gecco.2024.e02848. |
A probabilistic approach to post-wildfire debris-flow volume modeling | I. P. Donovan, P. M. Santi | 2017 | Donovan, I.P., and Santi, P.M., 2017, A probabilistic approach to post-wildfire debris-flow volume modeling: Landslides, v. 14, no. 4, p. 1345–1360, at https://doi.org/10.1007/s10346-016-0786-3. |
Meteorological environments associated with California wildfires and their potential roles in wildfire changes during 1984–2017 | L. Dong, L. R. Leung, Y. Qian, Y. F. Zou, F. F. Song, X. D. Chen | 2021 | Dong, L., Leung, L.R., Qian, Y., Zou, Y.F., Song, F.F., and Chen, X.D., 2021, Meteorological environments associated with California wildfires and their potential roles in wildfire changes during 1984–2017: Journal of Geophysical Research—Atmospheres, v. 126, no. 5, article e2020JD033180, at https://doi.org/10.1029/2020JD033180. |
Regeneration of montane forests 24 years after the 1988 Yellowstone fires—A fire-catalyzed shift in lower treelines? | D. C. Donato, B. J. Harvey, M. G. Turner | 2016 | Donato, D.C., Harvey, B.J., and Turner, M.G., 2016, Regeneration of montane forests 24 years after the 1988 Yellowstone fires—A fire-catalyzed shift in lower treelines?: Ecosphere, v. 7, no. 8, article e01410, at https://doi.org/10.1002/ecs2.1410. |
Does large area burned mean a bad fire year? Comparing contemporary wildfire years to historical fire regimes informs the restoration task in fire-dependent forests | D. C. Donato, J. S. Halofsky, D. J. Churchill, R. D. Haugo, C. Alina Cansler, A. Smith, B. J. Harvey | 2023 | Donato, D.C., Halofsky, J.S., Churchill, D.J., Haugo, R.D., Alina Cansler, C., Smith, A., and Harvey, B.J., 2023, Does large area burned mean a bad fire year? Comparing contemporary wildfire years to historical fire regimes informs the restoration task in fire-dependent forests: Forest Ecology and Management, v. 546, article 121372, at https://doi.org/10.1016/j.foreco.2023.121372. |
Southwestern ponderosa pine forest patterns following wildland fires managed for resource benefit differ from reference landscapes | J. J. Donager, A. J. Sánchez Meador, D. W. Huffman | 2022 | Donager, J.J., Sánchez Meador, A.J., and Huffman, D.W., 2022, Southwestern ponderosa pine forest patterns following wildland fires managed for resource benefit differ from reference landscapes: Landscape Ecology, v. 37, no. 1, p. 285–304, at https://doi.org/10.1007/s10980-021-01352-1. |
Short- and long-term effects of ponderosa pine fuel treatments intersected by the Egley Fire Complex, Oregon, USA | J. M. Dodge, E. K. Strand, A. T. Hudak, B. C. Bright, D. H. Hammond, B. A. Newingham | 2019 | Dodge, J.M., Strand, E.K., Hudak, A.T., Bright, B.C., Hammond, D.H., and Newingham, B.A., 2019, Short- and long-term effects of ponderosa pine fuel treatments intersected by the Egley Fire Complex, Oregon, USA: Fire Ecology, v. 15, no. 1, article 40, at https://doi.org/10.1186/s42408-019-0055-7. |
Aridity drives phylogenetic diversity and species richness patterns of nitrogen?fixing plants in North America | J. R. Doby, D. Li, R. A. Folk, C. M. Siniscalchi, R. P. Guralnick | 2022 | Doby, J.R., Li, D., Folk, R.A., Siniscalchi, C.M., and Guralnick, R.P., 2022, Aridity drives phylogenetic diversity and species richness patterns of nitrogen?fixing plants in North America: Global Ecology and Biogeography, v. 31, no. 8, p. 1630–1642, at https://doi.org/10.1111/geb.13535. |
Water quality and forest restoration in the Lake Tahoe Basin—Impacts of future management options | M. Dobre, J. W. Long, C. Maxwell, W. J. Elliot, R. Lew, E. S. Brooks, R. M. Scheller | 2022 | Dobre, M., Long, J.W., Maxwell, C., Elliot, W.J., Lew, R., Brooks, E.S., and Scheller, R.M., 2022, Water quality and forest restoration in the Lake Tahoe Basin—Impacts of future management options: Ecology and Society, v. 27, no. 2, article 6, at https://doi.org/10.5751/es-13133-270206. |
Satellite detection of canopy-scale tree mortality and survival from California wildfires with spatio-temporal deep learning | D. J. Dixon, Y. Zhu, C. F. Brown, Y. Jin | 2023 | Dixon, D.J., Zhu, Y., Brown, C.F., and Jin, Y., 2023, Satellite detection of canopy-scale tree mortality and survival from California wildfires with spatio-temporal deep learning: Remote Sensing of Environment, v. 298, article 113842, at https://doi.org/10.1016/j.rse.2023.113842. |
Influence of environmental change, harvest exposure, and human disturbance on population trends of greater sage-grouse | J. B. Dinkins, K. J. Lawson, J. L. Beck | 2021 | Dinkins, J.B., Lawson, K.J., and Beck, J.L., 2021, Influence of environmental change, harvest exposure, and human disturbance on population trends of greater sage-grouse: PLoS ONE, v. 16, no. 9, article e0257198, at https://doi.org/10.1371/journal.pone.0257198. |
Long-term persistence of desert rodent species in a Great Basin sagebrush community—Potential effects of fire, invasive annuals, and warming temperatures | L. A. Dimitri, W. S. Longland | 2022 | Dimitri, L.A., and Longland, W.S., 2022, Long-term persistence of desert rodent species in a Great Basin sagebrush community—Potential effects of fire, invasive annuals, and warming temperatures: Western North American Naturalist, v. 82, no. 3, p. 603–610, at https://doi.org/10.3398/064.082.0316. |
Pygmy rabbit habitat network reveals threats and opportunities for management and conservation | T. E. Dilts, K. A. Zeller, S. A. Cushman, E. S. Larrucea, M. M. Crowell, N. W. Byer, K. T. Shoemaker, M. D. Matocq | 2023 | Dilts, T.E., Zeller, K.A., Cushman, S.A., Larrucea, E.S., Crowell, M.M., Byer, N.W., Shoemaker, K.T., and Matocq, M.D., 2023, Pygmy rabbit habitat network reveals threats and opportunities for management and conservation: Landscape Ecology, v. 38, p. 1971–1989, at https://doi.org/10.1007/s10980-023-01672-4. |
Functionally relevant climate variables for arid lands—A climatic water deficit approach for modelling desert shrub distributions | T. E. Dilts, P. J. Weisberg, C. M. Dencker, J. C. Chambers | 2015 | Dilts, T.E., Weisberg, P.J., Dencker, C.M., and Chambers, J.C., 2015, Functionally relevant climate variables for arid lands—A climatic water deficit approach for modelling desert shrub distributions: Journal of Biogeography, v. 42, no. 10, p. 1986–1997, at https://doi.org/10.1111/jbi.12561. |
Both topography and climate affected forest and woodland burn severity in two regions of the western US, 1984 to 2006 | G. K. Dillon, Z. A. Holden, P. Morgan, M. A. Crimmins, E. K. Heyerdahl, C. H. Luce | 2011 | Dillon, G.K., Holden, Z.A., Morgan, P., Crimmins, M.A., Heyerdahl, E.K., and Luce, C.H., 2011, Both topography and climate affected forest and woodland burn severity in two regions of the western US, 1984 to 2006: Ecosphere, v. 2, no. 12, article 130, at https://doi.org/10.1890/es11-00271.1. |
Recent advances and emerging directions in fire detection systems based on machine learning algorithms | B. M. Diaconu | 2023 | Diaconu, B.M., 2023, Recent advances and emerging directions in fire detection systems based on machine learning algorithms: Fire, v. 6, no. 11, article 441, at https://doi.org/10.3390/fire6110441. |
OzCBI—The composite burn index adapted to assess fire severity and key fauna habitat features in Australian ecosystems | V. S. Densmore, R. J. van Dongen, R. Ong, B. G. Harris | 2023 | Densmore, V.S., van Dongen, R.J., Ong, R., and Harris, B.G., 2023, OzCBI—The composite burn index adapted to assess fire severity and key fauna habitat features in Australian ecosystems: Australian Forestry, v. 86, no. 1, p. 1–21, at https://doi.org/10.1080/00049158.2023.2168400. |
Severe weather experience and climate change belief among small woodland owners—A study of reciprocal effects | R. C. H. Denny, J. Marchese, A. P. Fischer | 2022 | Denny, R.C.H., Marchese, J., and Fischer, A.P., 2022, Severe weather experience and climate change belief among small woodland owners—A study of reciprocal effects: Weather, Climate, and Society, v. 14, no. 4, p. 1065–1082, at https://doi.org/10.1175/WCAS-D-21-0176.1. |
The effects of climate change event characteristics on experiences and response behaviors—A study of small woodland owners in the upper midwest, USA | R. C. H. Denny, A. P. Fischer | 2023 | Denny, R.C.H., and Fischer, A.P., 2023, The effects of climate change event characteristics on experiences and response behaviors—A study of small woodland owners in the upper midwest, USA: Frontiers in Climate, v. 5, article 1158386, at https://doi.org/10.3389/fclim.2023.1158386. |
Large wildfire trends in the western United States, 1984–2011 | P. E. Dennison, S. C. Brewer, J. D. Arnold, M. A. Moritz | 2014 | Dennison, P.E., Brewer, S.C., Arnold, J.D., and Moritz, M.A., 2014, Large wildfire trends in the western United States, 1984–2011: Geophysical Research Letters, v. 41, no. 8, p. 2928–2933, at https://doi.org/10.1002/2014GL059576. |
All-hazards dataset mined from the US National Incident Management System 1999–2020 | L. A. St. Denis, K. C. Short, K. McConnell, M. C. Cook, N. P. Mietkiewicz, M. Buckland, J. K. Balch | 2023 | St. Denis, L.A., Short, K.C., McConnell, K., Cook, M.C., Mietkiewicz, N.P., Buckland, M., and Balch, J.K., 2023, All-hazards dataset mined from the US National Incident Management System 1999–2020: Scientific Data, v. 10, no. 1, article 112, at https://doi.org/10.1038/s41597-023-01955-0. |
All-hazards dataset mined from the US National Incident Management System 1999–2014 | L. A. St Denis, N. P. Mietkiewicz, K. C. Short, M. Buckland, J. K. Balch | 2020 | St Denis, L.A., Mietkiewicz, N.P., Short, K.C., Buckland, M., and Balch, J.K., 2020, All-hazards dataset mined from the US National Incident Management System 1999–2014: Scientific Data, v. 7, no. 1, article 64, at https://doi.org/10.1038/s41597-020-0403-0. |
An ecoregional conservation assessment for forests and woodlands of the Mogollon Highlands ecoregion, northcentral Arizona and southwestern New Mexico, USA | D. A. DellaSala, A. L. Kuchy, M. Koopman, K. Menke, T. L. Fleischner, M. L. Floyd | 2023 | DellaSala, D.A., Kuchy, A.L., Koopman, M., Menke, K., Fleischner, T.L., and Floyd, M.L., 2023, An ecoregional conservation assessment for forests and woodlands of the Mogollon Highlands ecoregion, northcentral Arizona and southwestern New Mexico, USA: Land, v. 12, no. 12, article 2112, at https://doi.org/10.3390/land12122112. |
Accommodating mixed-severity fire to restore and maintain ecosystem integrity with a focus on the Sierra Nevada of California, USA | D. A. DellaSala, R. L. Hutto, C. T. Hanson, M. L. I. Bond, T., D. C. Odion, W. L. Baker | 2017 | DellaSala, D.A., Hutto, R.L., Hanson, C.T., Bond, M.L.I., T., Odion, D.C., and Baker, W.L., 2017, Accommodating mixed-severity fire to restore and maintain ecosystem integrity with a focus on the Sierra Nevada of California, USA: Fire Ecology, v. 13, no. 2, p. 148–171, at https://doi.org/10.4996/fireecology.130248173. |
Are wildland fires increasing large patches of complex early seral forest habitat? | D. A. DellaSala, C. T. Hanson | 2019 | DellaSala, D.A., and Hanson, C.T., 2019, Are wildland fires increasing large patches of complex early seral forest habitat?: Diversity, v. 11, no. 9, article 157, at https://doi.org/10.3390/d11090157. |
Black carbon concentrations in snow at Tronsen Meadow in central Washington from 2012 to 2013—Temporal and spatial variations and the role of local forest fire activity | I. Delaney, S. Kaspari, M. Jenkins | 2015 | Delaney, I., Kaspari, S., and Jenkins, M., 2015, Black carbon concentrations in snow at Tronsen Meadow in central Washington from 2012 to 2013—Temporal and spatial variations and the role of local forest fire activity: Journal of Geophysical Research—Atmospheres, v. 120, no. 18, p. 9160–9172, at https://doi.org/10.1002/2015JD023762. |
Fire-catalyzed vegetation shifts in ponderosa pine and Douglas-fir forests of the western United States | K. T. Davis, P. E. Higuera, S. Dobrowski, S. Parks, J. T. Abatzoglou, M. Rother, T. Veblen | 2020 | Davis, K.T., Higuera, P.E., Dobrowski, S., Parks, S., Abatzoglou, J.T., Rother, M., and Veblen, T., 2020, Fire-catalyzed vegetation shifts in ponderosa pine and Douglas-fir forests of the western United States: Environmental Research Letters, v. 15, no. 10, article 1040b8, at https://doi.org/10.1088/1748-9326/abb9df. |
Wildfires and climate change push low-elevation forests across a critical climate threshold for tree regeneration | K. T. Davis, S. Z. Dobrowski, P. E. Higuera, Z. A. Holden, T. T. Veblen, M. T. Rother, S. A. Parks, A. Sala, M. P. Maneta | 2019 | Davis, K.T., Dobrowski, S.Z., Higuera, P.E., Holden, Z.A., Veblen, T.T., Rother, M.T., Parks, S.A., Sala, A., and Maneta, M.P., 2019, Wildfires and climate change push low-elevation forests across a critical climate threshold for tree regeneration: Proceedings of the National Academy of Sciences of the United States of America, v. 116, no. 13, p. 6193–6198, at https://doi.org/10.1073/pnas.1815107116. |
Trajectories of change in sagebrush steppe vegetation communities in relation to multiple wildfires | G. M. Davies, J. D. Bakker, E. Dettweiler-Robinson, P. W. Dunwiddie, S. A. Hall, J. Downs, J. Evans | 2012 | Davies, G.M., Bakker, J.D., Dettweiler-Robinson, E., Dunwiddie, P.W., Hall, S.A., Downs, J., and Evans, J., 2012, Trajectories of change in sagebrush steppe vegetation communities in relation to multiple wildfires: Ecological Applications, v. 22, no. 5, p. 1562–1577, at https://doi.org/10.1890/10-2089.1. |
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Do vegetation fuel reduction treatments alter forest fire severity and carbon stability in California forests? | K. L. Daum, W. D. Hansen, J. Gellman, A. J. Plantinga, C. Jones, A. T. Trugman | 2024 | Daum, K.L., Hansen, W.D., Gellman, J., Plantinga, A.J., Jones, C., and Trugman, A.T., 2024, Do vegetation fuel reduction treatments alter forest fire severity and carbon stability in California forests?: Earth's Future, v. 12, no. 3, article e2023EF003763, at https://doi.org/10.1029/2023ef003763. |
Shifting Pacific storm tracks as stressors to ecosystems of western North America | M. P. Dannenberg, E. K. Wise | 2017 | Dannenberg, M.P., and Wise, E.K., 2017, Shifting Pacific storm tracks as stressors to ecosystems of western North America: Global Change Biology, v. 23, no. 11, p. 4896–4906, at https://doi.org/10.1111/gcb.13748. |
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Quantifying the contribution of major carbon producers to increases in vapor pressure deficit and burned area in western US and southwestern Canadian forests | K. A. Dahl, J. T. Abatzoglou, C. A. Phillips, J. P. Ortiz-Partida, R. Licker, L. D. Merner, B. Ekwurzel | 2023 | Dahl, K.A., Abatzoglou, J.T., Phillips, C.A., Ortiz-Partida, J.P., Licker, R., Merner, L.D., and Ekwurzel, B., 2023, Quantifying the contribution of major carbon producers to increases in vapor pressure deficit and burned area in western US and southwestern Canadian forests: Environmental Research Letters, v. 18, no. 6, article 064011, at https://doi.org/10.1088/1748-9326/acbce8. |
A new method comparing snowmelt timing with annual area burned | D. S. O’Leary, III, T. D. Bloom, J. C. Smith, C. R. Zemp, M. J. Medler | 2016 | O’Leary, D.S., III, Bloom, T.D., Smith, J.C., Zemp, C.R., and Medler, M.J., 2016, A new method comparing snowmelt timing with annual area burned: Fire Ecology, v. 12, no. 1, p. 41–51, at https://doi.org/10.4996/fireecology.1201041. |
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Post-fire early successional vegetation buffers surface microclimate and increases survival of planted conifer seedlings in the southwestern United States | J. L. Crockett, M. D. Hurteau | 2022 | Crockett, J.L., and Hurteau, M.D., 2022, Post-fire early successional vegetation buffers surface microclimate and increases survival of planted conifer seedlings in the southwestern United States: Canadian Journal of Forest Research, v. 52, no. 3, p. 416–425, at https://doi.org/10.1139/cjfr-2021-0221. |
Climate change and land management in the rangelands of central Oregon | M. K. Creutzburg, J. E. Halofsky, J. S. Halofsky, T. A. Christopher | 2015 | Creutzburg, M.K., Halofsky, J.E., Halofsky, J.S., and Christopher, T.A., 2015, Climate change and land management in the rangelands of central Oregon: Environmental Management, v. 55, no. 1, p. 43–55, at https://doi.org/10.1007/s00267-014-0362-3. |
Unfamiliar territory—Emerging themes for ecological drought research and management | S. D. Crausbay, J. Betancourt, J. Bradford, J. Cartwright, W. C. Dennison, J. Dunham, C. A. F. Enquist, A. G. Frazier, K. R. Hall, J. S. Littell, C. H. Luce, R. Palmer, A. R. Ramirez, I. Rangwala, L. Thompson, B. M. Walsh, S. Carter | 2020 | Crausbay, S.D., Betancourt, J., Bradford, J., Cartwright, J., Dennison, W.C., Dunham, J., Enquist, C.A.F., Frazier, A.G., Hall, K.R., et al., 2020, Unfamiliar territory—Emerging themes for ecological drought research and management: One Earth, v. 3, no. 3, p. 337–353, at https://doi.org/10.1016/j.oneear.2020.08.019. |
Influence of landscape-scale variables on vegetation conversion to exotic annual grassland in southern California, USA | R. D. Cox, K. L. Preston, R. F. Johnson, R. A. Minnich, E. B. Allen | 2014 | Cox, R.D., Preston, K.L., Johnson, R.F., Minnich, R.A., and Allen, E.B., 2014, Influence of landscape-scale variables on vegetation conversion to exotic annual grassland in southern California, USA: Global Ecology and Conservation, v. 2, p. 190–193, at https://doi.org/10.1016/j.gecco.2014.09.008. |
Influence of climate, post-treatment weather extremes, and soil factors on vegetation recovery after restoration treatments in the southwestern US | S. M. Copeland, S. M. Munson, J. B. Bradford, B. J. Butterfield | 2019 | Copeland, S.M., Munson, S.M., Bradford, J.B., and Butterfield, B.J., 2019, Influence of climate, post-treatment weather extremes, and soil factors on vegetation recovery after restoration treatments in the southwestern US: Applied Vegetation Science, v. 22, no. 1, p. 85–95, at https://doi.org/10.1111/avsc.12414. |
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Influences of prior wildfires on vegetation response to subsequent fire in a reburned southwestern landscape | J. D. Coop, S. A. Parks, S. R. McClernan, L. M. Holsinger | 2016 | Coop, J.D., Parks, S.A., McClernan, S.R., and Holsinger, L.M., 2016, Influences of prior wildfires on vegetation response to subsequent fire in a reburned southwestern landscape: Ecological Applications, v. 26, no. 2, p. 346–354, at https://doi.org/10.1890/15-0775. |
Contributions of fire refugia to resilient ponderosa pine and dry mixed-conifer forest landscapes | J. D. Coop, T. J. DeLory, W. M. Downing, S. L. Haire, M. A. Krawchuk, C. Miller, M.-A. Parisien, R. B. Walker | 2019 | Coop, J.D., DeLory, T.J., Downing, W.M., Haire, S.L., Krawchuk, M.A., Miller, C., Parisien, M.-A., and Walker, R.B., 2019, Contributions of fire refugia to resilient ponderosa pine and dry mixed-conifer forest landscapes: Ecosphere, v. 10, no. 7, article e02809, at https://doi.org/10.1002/ecs2.2809. |
Postfire futures in southwestern forests—Climate and landscape influences on trajectories of recovery and conversion | J. D. Coop | 2022 | Coop, J.D., 2022, Postfire futures in southwestern forests—Climate and landscape influences on trajectories of recovery and conversion: Ecological Applications, v. 33, no. 1, article e2725, at https://doi.org/10.1002/eap.2725. |
Resiliency of biological soil crusts and vascular plants varies among morphogroups with disturbance intensity | L. A. Condon, D. A. Pyke | 2018 | Condon, L.A., and Pyke, D.A., 2018, Resiliency of biological soil crusts and vascular plants varies among morphogroups with disturbance intensity: Plant and Soil, v. 433, no. 1-2, p. 271–287, at https://doi.org/10.1007/s11104-018-3838-8. |
Fire and grazing influence site resistance to Bromus tectorum through their effects on shrub, bunchgrass and biocrust communities in the Great Basin (USA) | L. A. Condon, D. A. Pyke | 2018 | Condon, L.A., and Pyke, D.A., 2018, Fire and grazing influence site resistance to Bromus tectorum through their effects on shrub, bunchgrass and biocrust communities in the Great Basin (USA): Ecosystems, v. 21, no. 7, p. 1416–1431, at https://doi.org/10.1007/s10021-018-0230-8. |
Quantifying edges as gradients at multiple scales improves habitat selection models for northern spotted owl | E. J. Comfort, D. A. Clark, R. G. Anthony, J. Bailey, M. G. Betts | 2016 | Comfort, E.J., Clark, D.A., Anthony, R.G., Bailey, J., and Betts, M.G., 2016, Quantifying edges as gradients at multiple scales improves habitat selection models for northern spotted owl: Landscape Ecology, v. 31, no. 6, p. 1227–1240, at https://doi.org/10.1007/s10980-015-0330-1. |
A CONUS-scale study of wildfire and evapotranspiration—Spatial and temporal response and controlling factors | N. M. Collar, S. Saxe, A. J. Rust, T. S. Hogue | 2021 | Collar, N.M., Saxe, S., Rust, A.J., and Hogue, T.S., 2021, A CONUS-scale study of wildfire and evapotranspiration—Spatial and temporal response and controlling factors: Journal of Hydrology, v. 603, article 127162, at https://doi.org/10.1016/j.jhydrol.2021.127162. |
Linking fire-induced evapotranspiration shifts to streamflow magnitude and timing in the western United States | N. M. Collar, S. Saxe, B. A. Ebel, K. S. Boden, A. J. Rust, T. S. Hogue | 2022 | Collar, N.M., Saxe, S., Ebel, B.A., Boden, K.S., Rust, A.J., and Hogue, T.S., 2022, Linking fire-induced evapotranspiration shifts to streamflow magnitude and timing in the western United States: Journal of Hydrology, v. 612, Pt. B, article 128242, at https://doi.org/10.1016/j.jhydrol.2022.128242. |
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Outbreaks of Douglas-fir beetle follow western spruce budworm defoliation in the Southern Rocky Mountains, USA | H. M. Cole, R. A. Andrus, C. Butkiewicz, K. C. Rodman, O. Santiago, N. J. Tutland, A. Waupochick, S. J. Hart | 2022 | Cole, H.M., Andrus, R.A., Butkiewicz, C., Rodman, K.C., Santiago, O., Tutland, N.J., Waupochick, A., and Hart, S.J., 2022, Outbreaks of Douglas-fir beetle follow western spruce budworm defoliation in the Southern Rocky Mountains, USA: Forests, v. 13, no. 3, article 371, at https://doi.org/10.3390/f13030371. |
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Wildfire, climate, and invasive grass interactions negatively impact an indicator species by reshaping sagebrush ecosystems | P. S. Coates, M. A. Ricca, B. G. Prochazka, M. L. Brooks, K. E. Doherty, T. Kroger, E. J. Blomberg, C. A. Hagen, M. L. Casazza | 2016 | Coates, P.S., Ricca, M.A., Prochazka, B.G., Brooks, M.L., Doherty, K.E., Kroger, T., Blomberg, E.J., Hagen, C.A., and Casazza, M.L., 2016, Wildfire, climate, and invasive grass interactions negatively impact an indicator species by reshaping sagebrush ecosystems: Proceedings of the National Academy of Sciences of the United States of America, v. 113, no. 45, p. 12745–12750, at https://doi.org/10.1073/pnas.1606898113. |
The relative importance of biotic and abiotic factors influencing aspen recruitment in Arizona | M. J. Clement, L. E. Harding, R. W. Lucas, E. S. Rubin | 2019 | Clement, M.J., Harding, L.E., Lucas, R.W., and Rubin, E.S., 2019, The relative importance of biotic and abiotic factors influencing aspen recruitment in Arizona: Forest Ecology and Management, v. 441, p. 32–41, at https://doi.org/10.1016/j.foreco.2019.03.026. |
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Divergent shrub-cover responses driven by climate, wildfire, and permafrost interactions in Arctic tundra ecosystems | Y. Chen, F. S. Hu, M. J. Lara | 2021 | Chen, Y., Hu, F.S., and Lara, M.J., 2021, Divergent shrub-cover responses driven by climate, wildfire, and permafrost interactions in Arctic tundra ecosystems: Global Change Biology, v. 27, no. 3, p. 652–663, at https://doi.org/10.1111/gcb.15451. |
Detecting post-fire burn severity and vegetation recovery using multitemporal remote sensing spectral indices and field-collected composite burn index data in a ponderosa pine forest | X. Chen, J. E. Vogelmann, M. Rollins, D. Ohlen, C. H. Key, L. Yang, C. Huang, H. Shi | 2011 | Chen, X., Vogelmann, J.E., Rollins, M., Ohlen, D., Key, C.H., Yang, L., Huang, C., and Shi, H., 2011, Detecting post-fire burn severity and vegetation recovery using multitemporal remote sensing spectral indices and field-collected composite burn index data in a ponderosa pine forest: International Journal of Remote Sensing, v. 32, no. 23, p. 7905–7927, at https://doi.org/10.1080/01431161.2010.524678. |
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Wildland fire detection and monitoring using a drone-collected RGB/IR image dataset | X. Chen, B. Hopkins, H. Wang, L. O'Neill, F. Afghah, A. Razi, P. Fule, J. Coen, E. Rowell, A. Watts | 2022 | Chen, X., Hopkins, B., Wang, H., O'Neill, L., Afghah, F., Razi, A., Fule, P., Coen, J., Rowell, E., and Watts, A., 2022, Wildland fire detection and monitoring using a drone-collected RGB/IR image dataset: IEEE Access, v. 10, p. 121301–121317, at https://doi.org/10.1109/access.2022.3222805. |
Soil water repellency after wildfires in the Blue Ridge Mountains, United States | J. J. Chen, L. A. Pangle, J. P. Gannon, R. D. Stewart | 2020 | Chen, J.J., Pangle, L.A., Gannon, J.P., and Stewart, R.D., 2020, Soil water repellency after wildfires in the Blue Ridge Mountains, United States: International Journal of Wildland Fire, v. 29, no. 11, p. 1009–1020, at https://doi.org/10.1071/Wf20055. |
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Missing burns in the high northern latitudes—The case for regionally focused burned area products | D. Chen, V. Shevade, A. E. Baer, T. V. Loboda | 2021 | Chen, D., Shevade, V., Baer, A.E., and Loboda, T.V., 2021, Missing burns in the high northern latitudes—The case for regionally focused burned area products: Remote Sensing, v. 13, no. 20, article 4145, at https://doi.org/10.3390/rs13204145. |
A systematic evaluation of influence of image selection process on remote sensing-based burn severity indices in North American boreal forest and tundra ecosystems | D. Chen, T. V. Loboda, J. V. Hall | 2020 | Chen, D., Loboda, T.V., and Hall, J.V., 2020, A systematic evaluation of influence of image selection process on remote sensing-based burn severity indices in North American boreal forest and tundra ecosystems: ISPRS Journal of Photogrammetry and Remote Sensing, v. 159, p. 63–77, at https://doi.org/10.1016/j.isprsjprs.2019.11.011. |
Spatio-temporal patterns of optimal Landsat data for burn severity index calculations—Implications for high northern latitudes wildfire research | D. Chen, C. Fu, J. V. Hall, E. E. Hoy, T. V. Loboda | 2021 | Chen, D., Fu, C., Hall, J.V., Hoy, E.E., and Loboda, T.V., 2021, Spatio-temporal patterns of optimal Landsat data for burn severity index calculations—Implications for high northern latitudes wildfire research: Remote Sensing of Environment, v. 258, article 112393, at https://doi.org/10.1016/j.rse.2021.112393. |
Evaluating the relationships between wildfires and drought using machine learning | A. Chen | 2022 | Chen, A., 2022, Evaluating the relationships between wildfires and drought using machine learning: International Journal of Wildland Fire, v. 31, no. 3, p. 230–239, at https://doi.org/10.1071/WF21145. |
Still standing—Recent patterns of post-fire conifer refugia in ponderosa pine-dominated forests of the Colorado Front Range | T. B. Chapman, T. Schoennagel, T. T. Veblen, K. C. Rodman | 2020 | Chapman, T.B., Schoennagel, T., Veblen, T.T., and Rodman, K.C., 2020, Still standing—Recent patterns of post-fire conifer refugia in ponderosa pine-dominated forests of the Colorado Front Range: PLoS ONE, v. 15, no. 1, article e0226926, at https://doi.org/10.1371/journal.pone.0226926. |
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Modern pyromes—Biogeographical patterns of fire characteristics across the contiguous United States | M. E. Cattau, A. L. Mahood, J. K. Balch, C. A. Wessman | 2022 | Cattau, M.E., Mahood, A.L., Balch, J.K., and Wessman, C.A., 2022, Modern pyromes—Biogeographical patterns of fire characteristics across the contiguous United States: Fire, v. 5, no. 4, article 95, at https://doi.org/10.3390/fire5040095. |
Widespread severe wildfires under climate change lead to increased forest homogeneity in dry mixed-conifer forests | B. A. Cassell, R. M. Scheller, M. S. Lucash, M. D. Hurteau, E. L. Loudermilk | 2019 | Cassell, B.A., Scheller, R.M., Lucash, M.S., Hurteau, M.D., and Loudermilk, E.L., 2019, Widespread severe wildfires under climate change lead to increased forest homogeneity in dry mixed-conifer forests: Ecosphere, v. 10, no. 11, article e02934, at https://doi.org/10.1002/ecs2.2934. |
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Landscape topoedaphic features create refugia from drought and insect disturbance in a lodgepole and whitebark pine forest | J. Cartwright | 2018 | Cartwright, J., 2018, Landscape topoedaphic features create refugia from drought and insect disturbance in a lodgepole and whitebark pine forest: Forests, v. 9, no. 11, article 715, at https://doi.org/10.3390/f9110715. |
A 1,500-year synthesis of wildfire activity stratified by elevation from the U.S. Rocky Mountains | V. A. Carter, M. J. Power, Z. J. Lundeen, J. L. Morris, K. L. Petersen, A. Brunelle, R. S. Anderson, J. J. Shinker, L. Turney, R. Koll, P. J. Bartlein | 2018 | Carter, V.A., Power, M.J., Lundeen, Z.J., Morris, J.L., Petersen, K.L., Brunelle, A., Anderson, R.S., Shinker, J.J., Turney, L., et al., 2018, A 1,500-year synthesis of wildfire activity stratified by elevation from the U.S. Rocky Mountains: Quaternary International, v. 488, p. 107–119, at https://doi.org/10.1016/j.quaint.2017.06.051. |
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Wildfire and spruce beetle outbreak have mixed effects on below-canopy temperatures in a Rocky Mountain subalpine forest | A. R. Carlson, J. S. Sibold, J. F. Negron | 2021 | Carlson, A.R., Sibold, J.S., and Negron, J.F., 2021, Wildfire and spruce beetle outbreak have mixed effects on below-canopy temperatures in a Rocky Mountain subalpine forest: Journal of Biogeography, v. 48, no. 1, p. 216–230, at https://doi.org/10.1111/jbi.13994. |
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Previous wildfires and management treatments moderate subsequent fire severity | C. A. Cansler, V. R. Kane, P. F. Hessburg, J. T. Kane, S. M. A. Jeronimo, J. A. Lutz, N. A. Povak, D. J. Churchill, A. J. Larson | 2021 | Cansler, C.A., Kane, V.R., Hessburg, P.F., Kane, J.T., Jeronimo, S.M.A., Lutz, J.A., Povak, N.A., Churchill, D.J., and Larson, A.J., 2021, Previous wildfires and management treatments moderate subsequent fire severity: Forest Ecology and Management, v. 504, article 119764, at https://doi.org/10.1016/j.foreco.2021.119764. |
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Watershed-scale vegetation, water quantity, and water quality responses to wildfire in the southern Appalachian Mountain region, United States | P. V. Caldwell, K. J. Elliott, N. Liu, J. M. Vose, D. R. Zietlow, J. D. Knoepp | 2020 | Caldwell, P.V., Elliott, K.J., Liu, N., Vose, J.M., Zietlow, D.R., and Knoepp, J.D., 2020, Watershed-scale vegetation, water quantity, and water quality responses to wildfire in the southern Appalachian Mountain region, United States: Hydrological Processes, v. 34, no. 26, p. 5188–5209, at https://doi.org/10.1002/hyp.13922. |
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Carbon sequestration and biodiversity co-benefits of preserving forests in the western United States | P. C. Buotte, B. E. Law, W. J. Ripple, L. T. Berner | 2020 | Buotte, P.C., Law, B.E., Ripple, W.J., and Berner, L.T., 2020, Carbon sequestration and biodiversity co-benefits of preserving forests in the western United States: Ecological Applications, v. 30, no. 2, article e02039, at https://doi.org/10.1002/eap.2039. |
Capturing functional strategies and compositional dynamics in vegetation demographic models | P. C. Buotte, C. D. Koven, C. Xu, J. K. Shuman, M. L. Goulden, S. Levis, J. Katz, J. Ding, W. Ma, Z. Robbins, L. M. Kueppers | 2021 | Buotte, P.C., Koven, C.D., Xu, C., Shuman, J.K., Goulden, M.L., Levis, S., Katz, J., Ding, J., Ma, W., et al., 2021, Capturing functional strategies and compositional dynamics in vegetation demographic models: Biogeosciences, v. 18, no. 14, p. 4473–4490, at https://doi.org/10.5194/bg-18-4473-2021. |
Consistent spatial scaling of high-severity wildfire can inform expected future patterns of burn severity | M. S. Buonanduci, D. C. Donato, J. S. Halofsky, M. C. Kennedy, B. J. Harvey | 2023 | Buonanduci, M.S., Donato, D.C., Halofsky, J.S., Kennedy, M.C., and Harvey, B.J., 2023, Consistent spatial scaling of high-severity wildfire can inform expected future patterns of burn severity: Ecology Letters, v. 26, no. 10, p. 1687–1699, at https://doi.org/10.1111/ele.14282. |
Climate legacy and lag effects on dryland plant communities in the southwestern U.S | E. L. Bunting, S. M. Munson, M. L. Villarreal | 2017 | Bunting, E.L., Munson, S.M., and Villarreal, M.L., 2017, Climate legacy and lag effects on dryland plant communities in the southwestern U.S: Ecological Indicators, v. 74, p. 216–229, at https://doi.org/10.1016/j.ecolind.2016.10.024. |
Assessing plant production responses to climate across water-limited regions using Google Earth Engine | E. L. Bunting, S. M. Munson, J. B. Bradford | 2019 | Bunting, E.L., Munson, S.M., and Bradford, J.B., 2019, Assessing plant production responses to climate across water-limited regions using Google Earth Engine: Remote Sensing of Environment, v. 233, article 111379, at https://doi.org/10.1016/j.rse.2019.111379. |
Wildland fire reburning trends across the US West suggest only short-term negative feedback and differing climatic effects | B. Buma, S. Weiss, K. Hayes, M. Lucash | 2020 | Buma, B., Weiss, S., Hayes, K., and Lucash, M., 2020, Wildland fire reburning trends across the US West suggest only short-term negative feedback and differing climatic effects: Environmental Research Letters, v. 15, no. 3, article 034026, at https://doi.org/10.1088/1748-9326/ab6c70. |
Short?interval fires increasing in the Alaskan boreal forest as fire self?regulation decays across forest types | B. Buma, K. Hayes, S. Weiss, M. Lucash | 2022 | Buma, B., Hayes, K., Weiss, S., and Lucash, M., 2022, Short?interval fires increasing in the Alaskan boreal forest as fire self?regulation decays across forest types: Scientific Reports, v. 12, no. 1, article 4901, at https://doi.org/10.1038/s41598-022-08912-8. |
SMLFire1.0—A stochastic machine learning (SML) model for wildfire activity in the western United States | J. Buch, A. P. Williams, C. S. Juang, W. D. Hansen, P. Gentine | 2023 | Buch, J., Williams, A.P., Juang, C.S., Hansen, W.D., and Gentine, P., 2023, SMLFire1.0—A stochastic machine learning (SML) model for wildfire activity in the western United States: Geoscientific Model Development, v. 16, no. 12, p. 3407–3433, at https://doi.org/10.5194/gmd-16-3407-2023. |
Invasion of annual grasses following wildfire corresponds to maladaptive habitat selection by a sagebrush ecosystem indicator species | B. E. Brussee, P. S. Coates, S. T. O’Neil, M. L. Casazza, S. P. Espinosa, J. D. Boone, E. M. Ammon, S. C. Gardner, D. J. Delehanty | 2022 | Brussee, B.E., Coates, P.S., O’Neil, S.T., Casazza, M.L., Espinosa, S.P., Boone, J.D., Ammon, E.M., Gardner, S.C., and Delehanty, D.J., 2022, Invasion of annual grasses following wildfire corresponds to maladaptive habitat selection by a sagebrush ecosystem indicator species: Global Ecology and Conservation, v. 37, article e02147, at https://doi.org/10.1016/j.gecco.2022.e02147. |
Exploring relationships of spring green-up to moisture and temperature across Wyoming, U.S.A. | J. F. Brown, L. Ji, A. Gallant, M. Kauffman | 2018 | Brown, J.F., Ji, L., Gallant, A., and Kauffman, M., 2018, Exploring relationships of spring green-up to moisture and temperature across Wyoming, U.S.A.: International Journal of Remote Sensing, v. 40, no. 3, p. 956–984, at https://doi.org/10.1080/01431161.2018.1519642. |
US wildfire potential—A historical view and future projection using high-resolution climate data | E. K. Brown, J. Wang, Y. Feng | 2021 | Brown, E.K., Wang, J., and Feng, Y., 2021, US wildfire potential—A historical view and future projection using high-resolution climate data: Environmental Research Letters, v. 16, no. 3, article 034060, at https://doi.org/10.1088/1748-9326/aba868. |
Landscape effects of wildfire on permafrost distribution in interior Alaska derived from remote sensing | D. Brown, M. Jorgenson, K. Kielland, D. Verbyla, A. Prakash, J. Koch | 2016 | Brown, D., Jorgenson, M., Kielland, K., Verbyla, D., Prakash, A., and Koch, J., 2016, Landscape effects of wildfire on permafrost distribution in interior Alaska derived from remote sensing: Remote Sensing, v. 8, no. 8, article 654, at https://doi.org/10.3390/rs8080654. |
Mapping multiple insect outbreaks across large regions annually using Landsat time series data | B. C. Bright, A. T. Hudak, A. J. H. Meddens, J. M. Egan, C. L. Jorgensen | 2020 | Bright, B.C., Hudak, A.T., Meddens, A.J.H., Egan, J.M., and Jorgensen, C.L., 2020, Mapping multiple insect outbreaks across large regions annually using Landsat time series data: Remote Sensing, v. 12, no. 10, article 1655, at https://doi.org/10.3390/rs12101655. |
Multitemporal lidar captures heterogeneity in fuel loads and consumption on the Kaibab Plateau | B. C. Bright, A. T. Hudak, T. R. McCarley, A. Spannuth, N. Sánchez-López, R. D. Ottmar, A. J. Soja | 2022 | Bright, B.C., Hudak, A.T., McCarley, T.R., Spannuth, A., Sánchez-López, N., Ottmar, R.D., and Soja, A.J., 2022, Multitemporal lidar captures heterogeneity in fuel loads and consumption on the Kaibab Plateau: Fire Ecology, v. 18, no. 1, article 18, at https://doi.org/10.1186/s42408-022-00142-7. |
Landsat time series and lidar as predictors of live and dead basal area across five bark beetle-affected forests | B. C. Bright, A. T. Hudak, R. E. Kennedy, A. J. H. Meddens | 2014 | Bright, B.C., Hudak, A.T., Kennedy, R.E., and Meddens, A.J.H., 2014, Landsat time series and lidar as predictors of live and dead basal area across five bark beetle-affected forests: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, v. 7, no. 8, p. 3440–3452, at https://doi.org/10.1109/JSTARS.2014.2346955. |
Examining post-fire vegetation recovery with Landsat time series analysis in three western North American forest types | B. C. Bright, A. T. Hudak, R. E. Kennedy, J. D. Braaten, A. H. Khalyani | 2019 | Bright, B.C., Hudak, A.T., Kennedy, R.E., Braaten, J.D., and Khalyani, A.H., 2019, Examining post-fire vegetation recovery with Landsat time series analysis in three western North American forest types: Fire Ecology, v. 15, article 8, at https://doi.org/10.1186/s42408-018-0021-9. |
Past variance and future projections of the environmental conditions driving western U.S. summertime wildfire burn area | S. J. Brey, E. A. Barnes, J. R. Pierce, A. L. S. Swann, E. V. Fischer | 2020 | Brey, S.J., Barnes, E.A., Pierce, J.R., Swann, A.L.S., and Fischer, E.V., 2020, Past variance and future projections of the environmental conditions driving western U.S. summertime wildfire burn area: Earth's Future, v. 9, no. 2, article e2020EF001645, at https://doi.org/10.1029/2020EF001645. |
Less fuel for the next fire? Short-interval fire delays forest recovery and interacting drivers amplify effects | K. H. Braziunas, N. G. Kiel, M. G. Turner | 2023 | Braziunas, K.H., Kiel, N.G., and Turner, M.G., 2023, Less fuel for the next fire? Short-interval fire delays forest recovery and interacting drivers amplify effects: Ecology, v. 104, no. 6, article e4042, at https://doi.org/10.1002/ecy.4042. |
Looking beyond the mean—Drivers of variability in postfire stand development of conifers in Greater Yellowstone | K. H. Braziunas, W. D. Hansen, R. Seidl, W. Rammer, M. G. Turner | 2018 | Braziunas, K.H., Hansen, W.D., Seidl, R., Rammer, W., and Turner, M.G., 2018, Looking beyond the mean—Drivers of variability in postfire stand development of conifers in Greater Yellowstone: Forest Ecology and Management, v. 430, p. 460–471, at https://doi.org/10.1016/j.foreco.2018.08.034. |
Young forests and fire—Using lidar-imagery fusion to explore fuels and burn severity in a subalpine forest reburn | K. H. Braziunas, D. C. Abendroth, M. G. Turner | 2022 | Braziunas, K.H., Abendroth, D.C., and Turner, M.G., 2022, Young forests and fire—Using lidar-imagery fusion to explore fuels and burn severity in a subalpine forest reburn: Ecosphere, v. 13, no. 5, article e4096, at https://doi.org/10.1002/ecs2.4096. |
Does increased forest protection correspond to higher fire severity in frequent-fire forests of the western United States? | C. M. Bradley, C. T. Hanson, D. A. DellaSala | 2016 | Bradley, C.M., Hanson, C.T., and DellaSala, D.A., 2016, Does increased forest protection correspond to higher fire severity in frequent-fire forests of the western United States?: Ecosphere, v. 7, no. 10, article e01492, at https://doi.org/10.1002/ecs2.1492. |
Fusing MODIS with Landsat 8 data to downscale weekly normalized difference vegetation index estimates for central Great Basin rangelands, USA | S. P. Boyte, B. K. Wylie, M. B. Rigge, D. Dahal | 2017 | Boyte, S.P., Wylie, B.K., Rigge, M.B., and Dahal, D., 2017, Fusing MODIS with Landsat 8 data to downscale weekly normalized difference vegetation index estimates for central Great Basin rangelands, USA: GIScience & Remote Sensing, v. 55, no. 3, p. 376–399, at https://doi.org/10.1080/15481603.2017.1382065. |
Validating a time series of annual grass percent cover in the sagebrush ecosystem | S. P. Boyte, B. K. Wylie, D. J. Major | 2019 | Boyte, S.P., Wylie, B.K., and Major, D.J., 2019, Validating a time series of annual grass percent cover in the sagebrush ecosystem: Rangeland Ecology & Management, v. 72, no. 2, p. 347–359, at https://doi.org/10.1016/j.rama.2018.09.004. |
Mapping and monitoring cheatgrass dieoff in rangelands of the northern Great Basin, USA | S. P. Boyte, B. K. Wylie, D. J. Major | 2015 | Boyte, S.P., Wylie, B.K., and Major, D.J., 2015, Mapping and monitoring cheatgrass dieoff in rangelands of the northern Great Basin, USA: Rangeland Ecology & Management, v. 68, no. 1, p. 18–28, at https://doi.org/10.1016/j.rama.2014.12.005. |
Estimating abiotic thresholds for sagebrush condition class in the western United States | S. P. Boyte, B. K. Wylie, Y. Gu, D. J. Major | 2020 | Boyte, S.P., Wylie, B.K., Gu, Y., and Major, D.J., 2020, Estimating abiotic thresholds for sagebrush condition class in the western United States: Rangeland Ecology & Management, v. 73, no. 2, p. 297–308, at https://doi.org/10.1016/j.rama.2019.10.010. |
Near-real-time cheatgrass percent cover in the northern Great Basin, USA, 2015 | S. P. Boyte, B. K. Wylie | 2016 | Boyte, S.P., and Wylie, B.K., 2016, Near-real-time cheatgrass percent cover in the northern Great Basin, USA, 2015: Rangelands, v. 38, no. 5, p. 278–284, at https://doi.org/10.1016/j.rala.2016.08.002. |
Fire and local factors shape ectomycorrhizal fungal communities associated with Pinus ponderosa in mountains of the Madrean Sky Island Archipelago | E. A. Bowman, D. R. Hayden, A. E. Arnold | 2021 | Bowman, E.A., Hayden, D.R., and Arnold, A.E., 2021, Fire and local factors shape ectomycorrhizal fungal communities associated with Pinus ponderosa in mountains of the Madrean Sky Island Archipelago: Fungal Ecology, v. 49, article 101013, at https://doi.org/10.1016/j.funeco.2020.101013. |
Human exposure and sensitivity to globally extreme wildfire events | D. M. J. S. Bowman, G. J. Williamson, J. T. Abatzoglou, C. A. Kolden, M. A. Cochrane, A. M. S. Smith | 2017 | Bowman, D.M.J.S., Williamson, G.J., Abatzoglou, J.T., Kolden, C.A., Cochrane, M.A., and Smith, A.M.S., 2017, Human exposure and sensitivity to globally extreme wildfire events: Nature Ecology & Evolution, v. 1, article 0058, at https://doi.org/10.1038/s41559-016-0058. |
Vegetation fires in the Anthropocene | D. Bowman, C. A. Kolden, J. T. Abatzoglou, F. H. Johnston, G. R. van der Werf, M. Flannigan | 2020 | Bowman, D., Kolden, C.A., Abatzoglou, J.T., Johnston, F.H., van der Werf, G.R., and Flannigan, M., 2020, Vegetation fires in the Anthropocene: Nature Reviews Earth & Environment, v. 1, no. 10, p. 500–515, at https://doi.org/10.1038/s43017-020-0085-3. |
MODIS–Landsat fusion for large area 30 m burned area mapping | L. Boschetti, D. P. Roy, C. O. Justice, M. L. Humber | 2015 | Boschetti, L., Roy, D.P., Justice, C.O., and Humber, M.L., 2015, MODIS–Landsat fusion for large area 30 m burned area mapping: Remote Sensing of Environment, v. 161, p. 27–42, at https://doi.org/10.1016/j.rse.2015.01.022. |
Long-term vegetation response following post-fire straw mulching | J. D. Bontrager, P. Morgan, A. T. Hudak, P. R. Robichaud | 2019 | Bontrager, J.D., Morgan, P., Hudak, A.T., and Robichaud, P.R., 2019, Long-term vegetation response following post-fire straw mulching: Fire Ecology, v. 15, no. 1, article 22, at https://doi.org/10.1186/s42408-019-0037-9. |
Forest management, barred owls, and wildfire in northern spotted owl territories | M. L. Bond, T. Y. Chi, C. M. Bradley, D. A. DellaSala | 2022 | Bond, M.L., Chi, T.Y., Bradley, C.M., and DellaSala, D.A., 2022, Forest management, barred owls, and wildfire in northern spotted owl territories: Forests, v. 13, no. 10, article 1730, at https://doi.org/10.3390/f13101730. |
Foraging habitat selection by California spotted owls after fire | M. L. Bond, C. Bradley, D. E. Lee | 2016 | Bond, M.L., Bradley, C., and Lee, D.E., 2016, Foraging habitat selection by California spotted owls after fire: The Journal of Wildlife Management, v. 80, no. 7, p. 1290–1300, at https://doi.org/10.1002/jwmg.21112. |
Effects of wildfire on riparian trees in southeastern Arizona | C. E. Bock, J. H. Bock | 2014 | Bock, C.E., and Bock, J.H., 2014, Effects of wildfire on riparian trees in southeastern Arizona: The Southwestern Naturalist, v. 59, no. 4, p. 570–576, at https://doi.org/10.1894/JEM-08.1. |
Topography and fire legacies drive variable post-fire juvenile conifer regeneration in eastern Oregon, USA | A. E. Boag, M. J. Ducey, M. W. Palace, J. Hartter | 2020 | Boag, A.E., Ducey, M.J., Palace, M.W., and Hartter, J., 2020, Topography and fire legacies drive variable post-fire juvenile conifer regeneration in eastern Oregon, USA: Forest Ecology and Management, v. 474, article 118312, at https://doi.org/10.1016/j.foreco.2020.118312. |
Increased water yield and altered water partitioning follow wildfire in a forested catchment in the western United States | K. Blount, C. J. Ruybal, K. J. Franz, T. S. Hogue | 2020 | Blount, K., Ruybal, C.J., Franz, K.J., and Hogue, T.S., 2020, Increased water yield and altered water partitioning follow wildfire in a forested catchment in the western United States: Ecohydrology, v. 13, no. 1, article e2170, at https://doi.org/10.1002/eco.2170. |
The compounding consequences of wildfire and climate change for a high-elevation wildflower (Saxifraga austromontana) | T. D. S. Bloom, A. Flower, M. Medler, E. G. DeChaine | 2018 | Bloom, T.D.S., Flower, A., Medler, M., and DeChaine, E.G., 2018, The compounding consequences of wildfire and climate change for a high-elevation wildflower (Saxifraga austromontana): Journal of Biogeography, v. 45, no. 12, p. 2755–2765, at https://doi.org/10.1111/jbi.13441. |
Wildfire risk, salience, and housing development in the wildland–urban interface | K. J. Black, N. B. Irwin, S. J. McCoy | 2023 | Black, K.J., Irwin, N.B., and McCoy, S.J., 2023, Wildfire risk, salience, and housing development in the wildland–urban interface: Journal of Regional Science, v. 63, no. 4, p. 922–946, at https://doi.org/10.1111/jors.12644. |
Fire regimes of Utah—The past as prologue | J. D. Birch, J. A. Lutz | 2023 | Birch, J.D., and Lutz, J.A., 2023, Fire regimes of Utah—The past as prologue: Fire, v. 6, no. 11, article 423, at https://doi.org/10.3390/fire6110423. |
Heading and backing fire behaviours mediate the influence of fuels on wildfire energy | J. D. Birch, M. B. Dickinson, A. Reiner, E. E. Knapp, S. N. Dailey, C. Ewell, J. A. Lutz, J. R. Miesel | 2023 | Birch, J.D., Dickinson, M.B., Reiner, A., Knapp, E.E., Dailey, S.N., Ewell, C., Lutz, J.A., and Miesel, J.R., 2023, Heading and backing fire behaviours mediate the influence of fuels on wildfire energy: International Journal of Wildland Fire, v. 32, no. 8, p. 1244–1261, at https://doi.org/10.1071/WF22010. |
Is proportion burned severely related to daily area burned? | D. S. Birch, P. Morgan, C. A. Kolden, A. T. Hudak, A. M. S. Smith | 2014 | Birch, D.S., Morgan, P., Kolden, C.A., Hudak, A.T., and Smith, A.M.S., 2014, Is proportion burned severely related to daily area burned?: Environmental Research Letters, v. 9, no. 6, article 064011, at https://doi.org/10.1088/1748-9326/9/6/064011. |
Vegetation, topography and daily weather influenced burn severity in central Idaho and western Montana forests | D. S. Birch, P. Morgan, C. A. Kolden, J. T. Abatzoglou, G. K. Dillon, A. T. Hudak, A. M. S. Smith | 2015 | Birch, D.S., Morgan, P., Kolden, C.A., Abatzoglou, J.T., Dillon, G.K., Hudak, A.T., and Smith, A.M.S., 2015, Vegetation, topography and daily weather influenced burn severity in central Idaho and western Montana forests: Ecosphere, v. 6, no. 1, article 17, at https://doi.org/10.1890/ES14-00213.1. |
Santa Ana winds and predictors of wildfire progression in southern California | M. Billmire, N. H. F. French, T. Loboda, R. C. Owen, M. Tyner | 2014 | Billmire, M., French, N.H.F., Loboda, T., Owen, R.C., and Tyner, M., 2014, Santa Ana winds and predictors of wildfire progression in southern California: International Journal of Wildland Fire, v. 23, no. 8, p. 1119–1129, at https://doi.org/10.1071/WF13046. |
Late Holocene fire-climate relationships of the western San Juan Mountains, Colorado | E. R. Bigio, T. W. Swetnam, P. A. Pearthree | 2017 | Bigio, E.R., Swetnam, T.W., and Pearthree, P.A., 2017, Late Holocene fire-climate relationships of the western San Juan Mountains, Colorado: International Journal of Wildland Fire, v. 26, no. 11, p. 944–962, at https://doi.org/10.1071/WF16204. |
Variable wildfire impacts on the seasonal water temperatures of western US streams—A retrospective study | M. T. Beyene, S. G. Leibowitz, M. Snyder, J. L. Ebersole, V. W. Almquist | 2022 | Beyene, M.T., Leibowitz, S.G., Snyder, M., Ebersole, J.L., and Almquist, V.W., 2022, Variable wildfire impacts on the seasonal water temperatures of western US streams—A retrospective study: PLoS ONE, v. 17, no. 7, article e0268452, at https://doi.org/10.1371/journal.pone.0268452. |
Parsing weather variability and wildfire effects on the post?fire changes in extreme daily stream flows—A quantile?based statistical approach and its application | M. T. Beyene, S. G. Leibowitz, M. J. Pennino | 2021 | Beyene, M.T., Leibowitz, S.G., and Pennino, M.J., 2021, Parsing weather variability and wildfire effects on the post?fire changes in extreme daily stream flows—A quantile?based statistical approach and its application: Water Resources Research, v. 57, no. 10, article e2020WR028029, at https://doi.org/10.1029/2020wr028029. |
To burn or not to burn—An empirical assessment of the impacts of wildfires and prescribed fires on trace element concentrations in western US streams | M. T. Beyene, S. G. Leibowitz, C. J. Dunn, K. D. Bladon | 2022 | Beyene, M.T., Leibowitz, S.G., Dunn, C.J., and Bladon, K.D., 2022, To burn or not to burn—An empirical assessment of the impacts of wildfires and prescribed fires on trace element concentrations in western US streams: Science of the Total Environment, v. 863, article 160731, at https://doi.org/10.1016/j.scitotenv.2022.160731. |
Heterogeneity in post-fire thermal responses across Pacific Northwest streams—A multi-site study | M. T. Beyene, S. G. Leibowitz | 2024 | Beyene, M.T., and Leibowitz, S.G., 2024, Heterogeneity in post-fire thermal responses across Pacific Northwest streams—A multi-site study: Journal of Hydrology X, v. 23, article 100173, at https://doi.org/10.1016/j.hydroa.2024.100173. |
Structural diversity and development in active fire regime mixed-conifer forests | J. K. Berkey, R. T. Belote, C. T. Maher, A. J. Larson | 2021 | Berkey, J.K., Belote, R.T., Maher, C.T., and Larson, A.J., 2021, Structural diversity and development in active fire regime mixed-conifer forests: Forest Ecology and Management, v. 479, article 118548, at https://doi.org/10.1016/j.foreco.2020.118548. |
Wildfire across agricultural landscapes—Farmer and rancher experiences and perceptions in the southern Great Plains | J. S. Bergtold, M. M. Caldas, A. Joslin, M. Gharib | in press | Bergtold, J.S., Caldas, M.M., Joslin, A., and Gharib, M., in press, Wildfire across agricultural landscapes—Farmer and rancher experiences and perceptions in the southern Great Plains: Environmental Hazards, at https://doi.org/10.1080/17477891.2024.2304201. |
Distribution and frequency of wildfire in California riparian ecosystems | J. Bendix, M. G. Commons | 2017 | Bendix, J., and Commons, M.G., 2017, Distribution and frequency of wildfire in California riparian ecosystems: Environmental Research Letters, v. 12, no. 7, article 075008, at https://doi.org/10.1088/1748-9326/aa7087. |
The role of previous fires in the management and expenditures of subsequent large wildfires | E. J. Belval, C. D. O’Connor, M. P. Thompson, M. S. Hand | 2019 | Belval, E.J., O’Connor, C.D., Thompson, M.P., and Hand, M.S., 2019, The role of previous fires in the management and expenditures of subsequent large wildfires: Fire, v. 2, no. 4, article 57, at https://doi.org/10.3390/fire2040057. |
Tree survival scales to community-level effects following mixed-severity fire in a mixed-conifer forest | R. Travis Belote, A. J. Larson, M. S. Dietz | 2015 | Travis Belote, R., Larson, A.J., and Dietz, M.S., 2015, Tree survival scales to community-level effects following mixed-severity fire in a mixed-conifer forest: Forest Ecology and Management, v. 353, p. 221–231, at https://doi.org/10.1016/j.foreco.2015.05.033. |
Imputed forest structure uncertainty varies across elevational and longitudinal gradients in the western Cascade Mountains, Oregon, USA | D. M. Bell, M. J. Gregory, J. L. Ohmann | 2015 | Bell, D.M., Gregory, M.J., and Ohmann, J.L., 2015, Imputed forest structure uncertainty varies across elevational and longitudinal gradients in the western Cascade Mountains, Oregon, USA: Forest Ecology and Management, v. 358, p. 154–164, at https://doi.org/10.1016/j.foreco.2015.09.007. |
Can low-severity fire reverse compositional change in montane forests of the Sierra Nevada, California, USA? | K. M. L. Becker, J. A. Lutz | 2016 | Becker, K.M.L., and Lutz, J.A., 2016, Can low-severity fire reverse compositional change in montane forests of the Sierra Nevada, California, USA?: Ecosphere, v. 7, no. 12, article e01484, at https://doi.org/10.1002/ecs2.1484. |
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The impact of wildfire on baseflow recession rates in California | R. R. Bart, C. L. Tague | 2017 | Bart, R.R., and Tague, C.L., 2017, The impact of wildfire on baseflow recession rates in California: Hydrological Processes, v. 31, no. 8, p. 1662–1673, at https://doi.org/10.1002/hyp.11141. |
Effects of ownership patterns on cross-boundary wildfires | A. M. G. Barros, M. A. Day, T. A. Spies, A. A. Ager | 2021 | Barros, A.M.G., Day, M.A., Spies, T.A., and Ager, A.A., 2021, Effects of ownership patterns on cross-boundary wildfires: Scientific Reports, v. 11, no. 1, article 19319, at https://doi.org/10.1038/s41598-021-98730-1. |
Spatiotemporal dynamics of simulated wildfire, forest management, and forest succession in central Oregon, USA | A. M. G. Barros, A. A. Ager, M. A. Day, H. K. Preisler, T. A. Spies, E. White, R. J. Pabst, K. A. Olsen, E. Platt, J. D. Bailey, J. P. Bolte | 2017 | Barros, A.M.G., Ager, A.A., Day, M.A., Preisler, H.K., Spies, T.A., White, E., Pabst, R.J., Olsen, K.A., Platt, E., et al., 2017, Spatiotemporal dynamics of simulated wildfire, forest management, and forest succession in central Oregon, USA: Ecology and Society, v. 22, no. 1, article 24, at https://doi.org/10.5751/ES-08917-220124. |
Improving long-term fuel treatment effectiveness in the National Forest System through quantitative prioritization | A. M. G. Barros, A. A. Ager, M. A. Day, P. Palaiologou | 2019 | Barros, A.M.G., Ager, A.A., Day, M.A., and Palaiologou, P., 2019, Improving long-term fuel treatment effectiveness in the National Forest System through quantitative prioritization: Forest Ecology and Management, v. 433, p. 514–527, at https://doi.org/10.1016/j.foreco.2018.10.041. |
Surface water quality after the Woolsey Fire in southern California | S. M. Barron, N. Mladenov, K. E. Sant, A. M. Kinoshita | 2022 | Barron, S.M., Mladenov, N., Sant, K.E., and Kinoshita, A.M., 2022, Surface water quality after the Woolsey Fire in southern California: Water, Air, and Soil Pollution, v. 233, no. 9, article 377, at https://doi.org/10.1007/s11270-022-05844-x. |
Wildfire influences individual growth and breeding dispersal, but not survival and recruitment in a montane amphibian | G. M. Barrile, A. D. Chalfoun, W. A. Estes-Zumpf, A. W. Walters | 2022 | Barrile, G.M., Chalfoun, A.D., Estes-Zumpf, W.A., and Walters, A.W., 2022, Wildfire influences individual growth and breeding dispersal, but not survival and recruitment in a montane amphibian: Ecosphere, v. 13, no. 8, article e4212, at https://doi.org/10.1002/ecs2.4212. |
Potential shifts in dominant forest cover in interior Alaska driven by variations in fire severity | K. Barrett, A. D. McGuire, E. E. Hoy, E. S. Kasischke | 2011 | Barrett, K., McGuire, A.D., Hoy, E.E., and Kasischke, E.S., 2011, Potential shifts in dominant forest cover in interior Alaska driven by variations in fire severity: Ecological Applications, v. 21, no. 7, p. 2380–2396, at https://doi.org/10.1890/10-0896.1. |
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Modeling fire severity in black spruce stands in the Alaskan boreal forest using spectral and non-spectral geospatial data | K. Barrett, E. S. Kasischke, A. D. McGuire, M. R. Turetsky, E. S. Kane | 2010 | Barrett, K., Kasischke, E.S., McGuire, A.D., Turetsky, M.R., and Kane, E.S., 2010, Modeling fire severity in black spruce stands in the Alaskan boreal forest using spectral and non-spectral geospatial data: Remote Sensing of Environment, v. 114, no. 7, p. 1494–1503, at https://doi.org/10.1016/j.rse.2010.02.001. |
Beyond fuel treatment effectiveness—Characterizing interactions between fire and treatments in the US | K. Barnett, S. A. Parks, C. Miller, H. T. Naughton | 2016 | Barnett, K., Parks, S.A., Miller, C., and Naughton, H.T., 2016, Beyond fuel treatment effectiveness—Characterizing interactions between fire and treatments in the US: Forests, v. 7, no. 10, article 237, at https://doi.org/10.3390/f7100237. |
The effects of crown scorch on post-fire delayed mortality are modified by drought exposure in California (USA) | J. S. Barker, A. N. Gray, J. S. Fried | 2022 | Barker, J.S., Gray, A.N., and Fried, J.S., 2022, The effects of crown scorch on post-fire delayed mortality are modified by drought exposure in California (USA): Fire, v. 5, no. 1, article 21, at https://doi.org/10.3390/fire5010021. |
Multi-scalar influence of weather and climate on very large-fires in the eastern United States | R. Barbero, J. T. Abatzoglou, C. A. Kolden, K. C. Hegewisch, N. K. Larkin, H. Podschwit | 2015 | Barbero, R., Abatzoglou, J.T., Kolden, C.A., Hegewisch, K.C., Larkin, N.K., and Podschwit, H., 2015, Multi-scalar influence of weather and climate on very large-fires in the eastern United States: International Journal of Climatology, v. 35, no. 8, p. 2180–2186, at https://doi.org/10.1002/joc.4090. |
Seasonal reversal of the influence of El Niño–Southern Oscillation on very large wildfire occurrence in the interior northwestern United States | R. Barbero, J. T. Abatzoglou, T. J. Brown | 2015 | Barbero, R., Abatzoglou, J.T., and Brown, T.J., 2015, Seasonal reversal of the influence of El Niño–Southern Oscillation on very large wildfire occurrence in the interior northwestern United States: Geophysical Research Letters, v. 42, no. 9, article 2015GL063428, at https://doi.org/10.1002/2015GL063428. |
Wildfires increasingly impact western US fluvial networks | G. Ball, P. Regier, R. Gonzalez-Pinzon, J. Reale, D. Van Horn | 2021 | Ball, G., Regier, P., Gonzalez-Pinzon, R., Reale, J., and Van Horn, D., 2021, Wildfires increasingly impact western US fluvial networks: Nature Communications, v. 12, no. 1, article 2484, at https://doi.org/10.1038/s41467-021-22747-3. |
Social-environmental extremes—Rethinking extraordinary events as outcomes of interacting biophysical and social systems | J. K. Balch, V. Iglesias, A. E. Braswell, M. W. Rossi, M. B. Joseph, A. L. Mahood, T. R. Shrum, C. T. White, V. M. Scholl, B. McGuire, C. Karban, M. Buckland, W. R. Travis | 2020 | Balch, J.K., Iglesias, V., Braswell, A.E., Rossi, M.W., Joseph, M.B., Mahood, A.L., Shrum, T.R., White, C.T., Scholl, V.M., et al., 2020, Social-environmental extremes—Rethinking extraordinary events as outcomes of interacting biophysical and social systems: Earth's Future, v. 8, no. 7, article e2019EF001319, at https://doi.org/10.1029/2019ef001319. |
FIRED (Fire Events Delineation)—An open, flexible algorithm and database of US fire events derived from the MODIS Burned Area Product (2001–2019) | J. K. Balch, L. A. St. Denis, A. L. Mahood, N. P. Mietkiewicz, T. M. Williams, J. McGlinchy, M. C. Cook | 2020 | Balch, J.K., St. Denis, L.A., Mahood, A.L., Mietkiewicz, N.P., Williams, T.M., McGlinchy, J., and Cook, M.C., 2020, FIRED (Fire Events Delineation)—An open, flexible algorithm and database of US fire events derived from the MODIS Burned Area Product (2001–2019): Remote Sensing, v. 12, no. 21, article 3498, at https://doi.org/10.3390/rs12213498. |
Human-started wildfires expand the fire niche across the United States | J. K. Balch, B. A. Bradley, J. T. Abatzoglou, R. C. Nagy, E. J. Fusco, A. L. Mahood | 2017 | Balch, J.K., Bradley, B.A., Abatzoglou, J.T., Nagy, R.C., Fusco, E.J., and Mahood, A.L., 2017, Human-started wildfires expand the fire niche across the United States: Proceedings of the National Academy of Sciences of the United States of America, v. 114, no. 11, p. 2946–2951, at https://doi.org/10.1073/pnas.1617394114. |
Warming weakens the night-time barrier to global fire | J. K. Balch, J. T. Abatzoglou, M. B. Joseph, M. J. Koontz, A. L. Mahood, J. McGlinchy, M. E. Cattau, A. P. Williams | 2022 | Balch, J.K., Abatzoglou, J.T., Joseph, M.B., Koontz, M.J., Mahood, A.L., McGlinchy, J., Cattau, M.E., and Williams, A.P., 2022, Warming weakens the night-time barrier to global fire: Nature, v. 602, no. 7897, p. 442–448, at https://doi.org/10.1038/s41586-021-04325-1. |
Switching on the big burn of 2017 | J. Balch, T. Schoennagel, A. Williams, J. Abatzoglou, M. Cattau, N. Mietkiewicz, L. St. Denis | 2018 | Balch, J., Schoennagel, T., Williams, A., Abatzoglou, J., Cattau, M., Mietkiewicz, N., and St. Denis, L., 2018, Switching on the big burn of 2017: Fire, v. 1, no. 1, article 17, at https://doi.org/10.3390/fire1010017. |
Harnessing natural disturbances—A nature-based solution for restoring and adapting dry forests in the western USA to climate change | W. L. Baker, C. T. Hanson, D. A. DellaSala | 2023 | Baker, W.L., Hanson, C.T., and DellaSala, D.A., 2023, Harnessing natural disturbances—A nature-based solution for restoring and adapting dry forests in the western USA to climate change: Fire, v. 6, no. 11, article 428, at https://doi.org/10.3390/fire6110428. |
Fire-history implications of fire scarring | W. L. Baker, A. J. Dugan | 2013 | Baker, W.L., and Dugan, A.J., 2013, Fire-history implications of fire scarring: Canadian Journal of Forest Research, v. 43, no. 10, p. 951–962, at https://doi.org/10.1139/cjfr-2013-0176. |
Tree-regeneration decline and type-conversion after high-severity fires will likely cause little western USA Forest loss from climate change | W. L. Baker | 2023 | Baker, W.L., 2023, Tree-regeneration decline and type-conversion after high-severity fires will likely cause little western USA Forest loss from climate change: Climate, v. 11, no. 11, article 214, at https://doi.org/10.3390/cli11110214. |
Is climate change restoring historical fire regimes across temperate landscapes of the San Juan Mountains, Colorado, USA? | W. L. Baker | 2022 | Baker, W.L., 2022, Is climate change restoring historical fire regimes across temperate landscapes of the San Juan Mountains, Colorado, USA?: Land, v. 11, no. 10, article 1615, at https://doi.org/10.3390/land11101615. |
Transitioning western U.S. dry forests to limited committed warming with bet-hedging and natural disturbances | W. L. Baker | 2018 | Baker, W.L., 2018, Transitioning western U.S. dry forests to limited committed warming with bet-hedging and natural disturbances: Ecosphere, v. 9, no. 6, article e02288, at https://doi.org/10.1002/ecs2.2288. |
Are high-severity fires burning at much higher rates recently than historically in dry-forest landscapes of the western USA? | W. L. Baker | 2015 | Baker, W.L., 2015, Are high-severity fires burning at much higher rates recently than historically in dry-forest landscapes of the western USA?: PLoS ONE, v. 10, no. 9, article e0136147, at https://doi.org/10.1371/journal.pone.0136147. |
Historical forest structure and fire in Sierran mixed-conifer forests reconstructed from General Land Office survey data | W. L. Baker | 2014 | Baker, W.L., 2014, Historical forest structure and fire in Sierran mixed-conifer forests reconstructed from General Land Office survey data: Ecosphere, v. 5, no. 7, article 79, at https://doi.org/10.1890/ES14-00046.1. |
Is wildland fire increasing in sagebrush landscapes of the western United States? | W. L. Baker | 2013 | Baker, W.L., 2013, Is wildland fire increasing in sagebrush landscapes of the western United States?: Annals of the Association of American Geographers, v. 103, no. 1, p. 5–19, at https://doi.org/10.1080/00045608.2012.732483. |
Implications of spatially extensive historical data from surveys for restoring dry forests of Oregon's eastern Cascades | W. L. Baker | 2012 | Baker, W.L., 2012, Implications of spatially extensive historical data from surveys for restoring dry forests of Oregon's eastern Cascades: Ecosphere, v. 3, no. 3, article 23, at https://doi.org/10.1890/ES11-00320.1. |
Historical fire regimes in ponderosa pine and mixed-conifer landscapes of the San Juan Mountains, Colorado, USA, from multiple sources | W. Baker | 2018 | Baker, W., 2018, Historical fire regimes in ponderosa pine and mixed-conifer landscapes of the San Juan Mountains, Colorado, USA, from multiple sources: Fire, v. 1, no. 2, article 23, at https://doi.org/10.3390/fire1020023. |
Historical seasonal changes in prescribed burn windows in California | J. A. Baijnath-Rodino, S. Li, A. Martinez, M. Kumar, L. N. Quinn-Davidson, R. A. York, T. Banerjee | 2022 | Baijnath-Rodino, J.A., Li, S., Martinez, A., Kumar, M., Quinn-Davidson, L.N., York, R.A., and Banerjee, T., 2022, Historical seasonal changes in prescribed burn windows in California: Science of the Total Environment, v. 836, article 155723, at https://doi.org/10.1016/j.scitotenv.2022.155723. |
A novel approach to estimating soil yield risk in fire prone ecosystems | K. J. Badik, C. Wilson, S. K. Kampf, L. Saito, L. Provencher, S. Byer, M. Hazelwood | 2022 | Badik, K.J., Wilson, C., Kampf, S.K., Saito, L., Provencher, L., Byer, S., and Hazelwood, M., 2022, A novel approach to estimating soil yield risk in fire prone ecosystems: Forest Ecology and Management, v. 505, article 119887, at https://doi.org/10.1016/j.foreco.2021.119887. |
California’s forest carbon offsets buffer pool is severely undercapitalized | G. Badgley, F. Chay, O. S. Chegwidden, J. J. Hamman, J. Freeman, D. Cullenward | 2022 | Badgley, G., Chay, F., Chegwidden, O.S., Hamman, J.J., Freeman, J., and Cullenward, D., 2022, California’s forest carbon offsets buffer pool is severely undercapitalized: Frontiers in Forests and Global Change, v. 5, article 930426, at https://doi.org/10.3389/ffgc.2022.930426. |
Integration of multiple spectral indices and a neural network for burned area mapping based on MODIS data | R. Ba, W. Song, X. Li, Z. Xie, S. Lo | 2019 | Ba, R., Song, W., Li, X., Xie, Z., and Lo, S., 2019, Integration of multiple spectral indices and a neural network for burned area mapping based on MODIS data: Remote Sensing, v. 11, no. 3, article 326, at https://doi.org/10.3390/rs11030326. |
Carbon emissions from the peat fire problem—A review | N. A. Che Azmi, N. Mohd Apandi, A. S. A. Rashid | 2021 | Che Azmi, N.A., Mohd Apandi, N., and A. Rashid, A.S., 2021, Carbon emissions from the peat fire problem—A review: Environmental Science and Pollution Research International, v. 28, no. 14, p. 16948–16961, at https://doi.org/10.1007/s11356-021-12886-x. |
Conterminous United States land-cover change (1985–2016)—New insights from annual time series | R. F. Auch, D. F. Wellington, J. L. Taylor, S. V. Stehman, H. J. Tollerud, J. F. Brown, T. R. Loveland, B. W. Pengra, J. A. Horton, Z. Zhu, A. A. Midekisa, K. L. Sayler, G. Z. Xian, C. P. Barber, R. R. Reker | 2022 | Auch, R.F., Wellington, D.F., Taylor, J.L., Stehman, S.V., Tollerud, H.J., Brown, J.F., Loveland, T.R., Pengra, B.W., Horton, J.A., et al., 2022, Conterminous United States land-cover change (1985–2016)—New insights from annual time series: Land, v. 11, no. 2, article 298, at https://doi.org/10.3390/land11020298. |
Spatial and temporal trends of drought effects in a heterogeneous semi-arid forest ecosystem | T. J. Assal, P. J. Anderson, J. Sibold | 2016 | Assal, T.J., Anderson, P.J., and Sibold, J., 2016, Spatial and temporal trends of drought effects in a heterogeneous semi-arid forest ecosystem: Forest Ecology and Management, v. 365, p. 137–151, at https://doi.org/10.1016/j.foreco.2016.01.017. |
A global wildfire dataset for the analysis of fire regimes and fire behaviour | T. Artes, D. Oom, D. de Rigo, T. H. Durrant, P. Maianti, G. Liberta, J. San-Miguel-Ayanz | 2019 | Artes, T., Oom, D., de Rigo, D., Durrant, T.H., Maianti, P., Liberta, G., and San-Miguel-Ayanz, J., 2019, A global wildfire dataset for the analysis of fire regimes and fire behaviour: Scientific Data, v. 6, no. 1, article 296, at https://doi.org/10.1038/s41597-019-0312-2. |
Modeling climate-fire connections within the Great Basin and upper Colorado River Basin, western United States | J. D. Arnold, S. C. Brewer, P. E. Dennison | 2014 | Arnold, J.D., Brewer, S.C., and Dennison, P.E., 2014, Modeling climate-fire connections within the Great Basin and upper Colorado River Basin, western United States: Fire Ecology, v. 10, no. 2, p. 64–75, at https://doi.org/10.4996/fireecology.1002064. |
Pattern and process of prescribed fires influence effectiveness at reducing wildfire severity in dry coniferous forests | R. S. Arkle, D. S. Pilliod, J. L. Welty | 2012 | Arkle, R.S., Pilliod, D.S., and Welty, J.L., 2012, Pattern and process of prescribed fires influence effectiveness at reducing wildfire severity in dry coniferous forests: Forest Ecology and Management, v. 276, p. 174–184, at https://doi.org/10.1016/j.foreco.2012.04.002. |
Quantifying restoration effectiveness using multi-scale habitat models—Implications for sage-grouse in the Great Basin | R. S. Arkle, D. S. Pilliod, S. E. Hanser, M. L. Brooks, J. C. Chambers, J. B. Grace, K. C. Knutson, D. A. Pyke, J. L. Welty, T. A. Wirth | 2014 | Arkle, R.S., Pilliod, D.S., Hanser, S.E., Brooks, M.L., Chambers, J.C., Grace, J.B., Knutson, K.C., Pyke, D.A., Welty, J.L., and Wirth, T.A., 2014, Quantifying restoration effectiveness using multi-scale habitat models—Implications for sage-grouse in the Great Basin: Ecosphere, v. 5, no. 3, article 31, at https://doi.org/10.1890/ES13-00278.1. |
Combining methods to estimate post-fire soil erosion using remote sensing data | I. Argentiero, G. F. Ricci, M. Elia, M. D'Este, V. Giannico, F. V. Ronco, F. Gentile, G. Sanesi | 2021 | Argentiero, I., Ricci, G.F., Elia, M., D'Este, M., Giannico, V., Ronco, F.V., Gentile, F., and Sanesi, G., 2021, Combining methods to estimate post-fire soil erosion using remote sensing data: Forests, v. 12, no. 8, article 1105, at https://doi.org/10.3390/f12081105. |
Northern Colorado Plateau piñon-juniper woodland decline over the past century | P. A. Arendt, W. L. Baker | 2013 | Arendt, P.A., and Baker, W.L., 2013, Northern Colorado Plateau piñon-juniper woodland decline over the past century: Ecosphere, v. 4, no. 8, article 103, at https://doi.org/10.1890/ES13-00081.1. |
Application of fractional techniques in the analysis of forest fires | M. Lopes António, J. A. T. Machado | 2016 | Lopes António, M., and Machado, J.A.T., 2016, Application of fractional techniques in the analysis of forest fires: International Journal of Nonlinear Sciences and Numerical Simulation, v. 17, no. 7-8, p. 381–390, at https://doi.org/10.1515/ijnsns-2016-0026. |
Does post-fire recovery of native grasses across abiotic-stress and invasive-grass gradients match theoretical predictions, in sagebrush steppe? | C. R. Anthony, M. J. Germino | 2023 | Anthony, C.R., and Germino, M.J., 2023, Does post-fire recovery of native grasses across abiotic-stress and invasive-grass gradients match theoretical predictions, in sagebrush steppe?: Global Ecology and Conservation, v. 42, article e02410, at https://doi.org/10.1016/j.gecco.2023.e02410. |
Predictive models of selective cattle use of large, burned landscapes in semiarid sagebrush-steppe | C. R. Anthony, M. J. Germino | 2022 | Anthony, C.R., and Germino, M.J., 2022, Predictive models of selective cattle use of large, burned landscapes in semiarid sagebrush-steppe: Rangeland Ecology & Management, v. 85, p. 1–8, at https://doi.org/10.1016/j.rama.2022.07.007. |
Fire severity unaffected by spruce beetle outbreak in spruce-fir forests in southwestern Colorado | R. A. Andrus, T. T. Veblen, B. J. Harvey, S. J. Hart | 2016 | Andrus, R.A., Veblen, T.T., Harvey, B.J., and Hart, S.J., 2016, Fire severity unaffected by spruce beetle outbreak in spruce-fir forests in southwestern Colorado: Ecological Applications, v. 26, no. 3, p. 700–11, at https://doi.org/10.1890/15-1121. |
Assessing the quality of fire refugia for wildlife habitat | R. A. Andrus, A. J. Martinez, G. M. Jones, A. J. H. Meddens | 2021 | Andrus, R.A., Martinez, A.J., Jones, G.M., and Meddens, A.J.H., 2021, Assessing the quality of fire refugia for wildlife habitat: Forest Ecology and Management, v. 482, article 118868, at https://doi.org/10.1016/j.foreco.2020.118868. |
Spatial and temporal drivers of post-fire tree establishment and height growth in a managed forest landscape | R. A. Andrus, C. A. Droske, M. C. Franz, A. T. Hudak, L. B. Lentile, S. A. Lewis, P. Morgan, P. R. Robichaud, A. J. H. Meddens | 2022 | Andrus, R.A., Droske, C.A., Franz, M.C., Hudak, A.T., Lentile, L.B., Lewis, S.A., Morgan, P., Robichaud, P.R., and Meddens, A.J.H., 2022, Spatial and temporal drivers of post-fire tree establishment and height growth in a managed forest landscape: Fire Ecology, v. 18, no. 1, article 29, at https://doi.org/10.1186/s42408-022-00153-4. |
Developing a set of indicators to identify, monitor, and track impacts and change in forests of the United States | S. M. Anderson, L. S. Heath, M. R. Emery, J. A. Hicke, J. S. Littell, A. Lucier, J. G. Masek, D. L. Peterson, R. Pouyat, K. M. Potter, G. Robertson, J. Sperry | 2021 | Anderson, S.M., Heath, L.S., Emery, M.R., Hicke, J.A., Littell, J.S., Lucier, A., Masek, J.G., Peterson, D.L., Pouyat, R., et al., 2021, Developing a set of indicators to identify, monitor, and track impacts and change in forests of the United States: Climatic Change, v. 165, no. 1-2, article 13, at https://doi.org/10.1007/s10584-021-02993-6. |
Inequality in agency response—Evidence from salient wildfire events | S. Anderson, A. J. Plantinga, M. Wibbenmeyer | 2023 | Anderson, S., Plantinga, A.J., and Wibbenmeyer, M., 2023, Inequality in agency response—Evidence from salient wildfire events: The Journal of Politics, v. 85, no. 2, p. 625–639, at https://doi.org/10.1086/722044. |
Canada lynx occupancy and density in Glacier National Park | A. K. Anderson, J. S. Waller, D. H. Thornton | 2023 | Anderson, A.K., Waller, J.S., and Thornton, D.H., 2023, Canada lynx occupancy and density in Glacier National Park: The Journal of Wildlife Management, v. 87, no. 4, article e22383, at https://doi.org/10.1002/jwmg.22383. |
Climate-driven risks to the climate mitigation potential of forests | W. R. L. Anderegg, A. T. Trugman, G. Badgley, C. M. Anderson, A. Bartuska, P. Ciais, D. Cullenward, C. B. Field, J. Freeman, S. J. Goetz, J. A. Hicke, D. Huntzinger, R. B. Jackson, J. Nickerson, S. Pacala, J. T. Randerson | 2020 | Anderegg, W.R.L., Trugman, A.T., Badgley, G., Anderson, C.M., Bartuska, A., Ciais, P., Cullenward, D., Field, C.B., Freeman, J., et al., 2020, Climate-driven risks to the climate mitigation potential of forests: Science, v. 368, no. 6497, article eaaz7005, at https://doi.org/10.1126/science.aaz7005. |
Climate change greatly escalates forest disturbance risks to US property values | W. R. L. Anderegg, T. Collins, S. Grineski, S. Nicholls, C. Nolte | 2023 | Anderegg, W.R.L., Collins, T., Grineski, S., Nicholls, S., and Nolte, C., 2023, Climate change greatly escalates forest disturbance risks to US property values: Environmental Research Letters, v. 18, no. 9, article 094011, at https://doi.org/10.1088/1748-9326/ace639. |
Future climate risks from stress, insects and fire across US forests | W. R. L. Anderegg, O. S. Chegwidden, G. Badgley, A. T. Trugman, D. Cullenward, J. T. Abatzoglou, J. A. Hicke, J. Freeman, J. J. Hamman | 2022 | Anderegg, W.R.L., Chegwidden, O.S., Badgley, G., Trugman, A.T., Cullenward, D., Abatzoglou, J.T., Hicke, J.A., Freeman, J., and Hamman, J.J., 2022, Future climate risks from stress, insects and fire across US forests: Ecological Letters, v. 25, no. 6, p. 1510–1520, at https://doi.org/10.1111/ele.14018. |
The Global Fire Atlas of individual fire size, duration, speed and direction | N. Andela, D. C. Morton, L. Giglio, R. Paugam, Y. Chen, S. Hantson, G. R. Van Der Werf, J. T. Anderson | 2019 | Andela, N., Morton, D.C., Giglio, L., Paugam, R., Chen, Y., Hantson, S., Van Der Werf, G.R., and Anderson, J.T., 2019, The Global Fire Atlas of individual fire size, duration, speed and direction: Earth System Science Data, v. 11, no. 2, p. 529–552, at https://doi.org/10.5194/essd-11-529-2019. |
Land and atmosphere precursors to fuel loading, wildfire ignition and post-fire recovery | M. R. Alizadeh, J. Adamowski, D. Entekhabi | 2024 | Alizadeh, M.R., Adamowski, J., and Entekhabi, D., 2024, Land and atmosphere precursors to fuel loading, wildfire ignition and post-fire recovery: Geophysical Research Letters, v. 51, no. 2, article e2023GL105324, at https://doi.org/10.1029/2023gl105324. |
Warming enabled upslope advance in western US forest fires | M. R. Alizadeh, J. T. Abatzoglou, C. H. Luce, J. F. Adamowski, A. Farid, M. Sadegh | 2021 | Alizadeh, M.R., Abatzoglou, J.T., Luce, C.H., Adamowski, J.F., Farid, A., and Sadegh, M., 2021, Warming enabled upslope advance in western US forest fires: Proceedings of the National Academy of Sciences of the United States of America, v. 118, no. 22, article e2009717118, at https://doi.org/10.1073/pnas.2009717118. |
The relative impacts of vegetation, topography and spatial arrangement on building loss to wildfires in case studies of California and Colorado | P. M. Alexandre, S. I. Stewart, M. H. Mockrin, N. S. Keuler, A. D. Syphard, A. Bar-Massada, M. K. Clayton, V. C. Radeloff | 2016 | Alexandre, P.M., Stewart, S.I., Mockrin, M.H., Keuler, N.S., Syphard, A.D., Bar-Massada, A., Clayton, M.K., and Radeloff, V.C., 2016, The relative impacts of vegetation, topography and spatial arrangement on building loss to wildfires in case studies of California and Colorado: Landscape Ecology, v. 31, no. 2, p. 415–430, at https://doi.org/10.1007/s10980-015-0257-6. |
Factors related to building loss due to wildfires in the conterminous United States | P. M. Alexandre, S. I. Stewart, N. S. Keuler, M. K. Clayton, M. H. Mockrin, A. Bar-Massada, A. D. Syphard, V. C. Radeloff | 2016 | Alexandre, P.M., Stewart, S.I., Keuler, N.S., Clayton, M.K., Mockrin, M.H., Bar-Massada, A., Syphard, A.D., and Radeloff, V.C., 2016, Factors related to building loss due to wildfires in the conterminous United States: Ecological Applications, v. 26, no. 7, p. 2323–2338, at https://doi.org/10.1002/eap.1376. |
Rebuilding and new housing development after wildfire | P. M. Alexandre, M. H. Mockrin, S. I. Stewart, R. B. Hammer, V. C. Radeloff | 2015 | Alexandre, P.M., Mockrin, M.H., Stewart, S.I., Hammer, R.B., and Radeloff, V.C., 2015, Rebuilding and new housing development after wildfire: International Journal of Wildland Fire, v. 24, no. 1, p. 138–149, at https://doi.org/10.1071/WF13197. |
Contrasting the efficiency of landscape versus community protection fuel treatment strategies to reduce wildfire exposure and risk | F. Alcasena, A. A. Ager, P. Belavenutti, M. Krawchuk, M. A. Day | 2022 | Alcasena, F., Ager, A.A., Belavenutti, P., Krawchuk, M., and Day, M.A., 2022, Contrasting the efficiency of landscape versus community protection fuel treatment strategies to reduce wildfire exposure and risk: Journal of Environmental Management, v. 309, article 114650, at https://doi.org/10.1016/j.jenvman.2022.114650. |
Drought sensitivity and trends of riparian vegetation vigor in Nevada, USA (1985–2018) | C. M. Albano, K. C. McGwire, M. B. Hausner, D. J. McEvoy, C. G. Morton, J. L. Huntington | 2020 | Albano, C.M., McGwire, K.C., Hausner, M.B., McEvoy, D.J., Morton, C.G., and Huntington, J.L., 2020, Drought sensitivity and trends of riparian vegetation vigor in Nevada, USA (1985–2018): Remote Sensing, v. 12, no. 9, article 1362, at https://doi.org/10.3390/RS12091362. |
Influence of atmospheric rivers on vegetation productivity and fire patterns in the southwestern US | C. M. Albano, M. D. Dettinger, C. E. Soulard | 2017 | Albano, C.M., Dettinger, M.D., and Soulard, C.E., 2017, Influence of atmospheric rivers on vegetation productivity and fire patterns in the southwestern US: Journal of Geophysical Research—Biogeosciences, v. 122, no. 2, p. 308–323, at https://doi.org/10.1002/2016jg003608. |
Changes in soil properties over time after a wildfire and implications to slope stability | I. D. Akin, T. O. Akinleye, P. R. Robichaud | 2023 | Akin, I.D., Akinleye, T.O., and Robichaud, P.R., 2023, Changes in soil properties over time after a wildfire and implications to slope stability: Journal of Geotechnical and Geoenvironmental Engineering, v. 149, no. 7, article 04023045, at https://doi.org/10.1061/jggefk.Gteng-11348. |
Droughts impede water balance recovery from fires in the western United States | S. K. Ahmad, T. R. Holmes, S. V. Kumar, T. M. Lahmers, P. W. Liu, W. Nie, A. Getirana, E. Orland, R. Bindlish, A. Guzman, C. R. Hain, F. S. Melton, K. A. Locke, Y. Yang | 2024 | Ahmad, S.K., Holmes, T.R., Kumar, S.V., Lahmers, T.M., Liu, P.W., Nie, W., Getirana, A., Orland, E., Bindlish, R., et al., 2024, Droughts impede water balance recovery from fires in the western United States: Nature Ecology and Evolution, v. 8, p. 229–238, at https://doi.org/10.1038/s41559-023-02266-8. |
Fire interval and post-fire climate effects on serotinous forest resilience | M. C. Agne, J. B. Fontaine, N. J. Enright, B. J. Harvey | 2022 | Agne, M.C., Fontaine, J.B., Enright, N.J., and Harvey, B.J., 2022, Fire interval and post-fire climate effects on serotinous forest resilience: Fire Ecology, v. 18, no. 1, article 22, at https://doi.org/10.1186/s42408-022-00145-4. |
Rapid fuel recovery after stand-replacing fire in closed-cone pine forests and implications for short-interval severe reburns | M. C. Agne, J. B. Fontaine, N. J. Enright, S. M. Bisbing, B. J. Harvey | 2023 | Agne, M.C., Fontaine, J.B., Enright, N.J., Bisbing, S.M., and Harvey, B.J., 2023, Rapid fuel recovery after stand-replacing fire in closed-cone pine forests and implications for short-interval severe reburns: Forest Ecology and Management, v. 545, article 121263, at https://doi.org/10.1016/j.foreco.2023.121263. |
Demographic processes underpinning post-fire resilience in California closed-cone pine forests—The importance of fire interval, stand structure, and climate | M. C. Agne, J. B. Fontaine, N. J. Enright, S. M. Bisbing, B. J. Harvey | 2022 | Agne, M.C., Fontaine, J.B., Enright, N.J., Bisbing, S.M., and Harvey, B.J., 2022, Demographic processes underpinning post-fire resilience in California closed-cone pine forests—The importance of fire interval, stand structure, and climate: Plant Ecology, v. 223, p. 751–767, at https://doi.org/10.1007/s11258-022-01228-7. |
Restoration of fire in managed forests—A model to prioritize landscapes and analyze tradeoffs | A. A. Ager, N. M. Vaillant, A. McMahan | 2013 | Ager, A.A., Vaillant, N.M., and McMahan, A., 2013, Restoration of fire in managed forests—A model to prioritize landscapes and analyze tradeoffs: Ecosphere, v. 4, no. 2, article 29, at https://doi.org/10.1890/ES13-00007.1. |
Assessing transboundary wildfire exposure in the southwestern United States | A. A. Ager, P. Palaiologou, C. R. Evers, M. A. Day, A. M. G. Barros | 2018 | Ager, A.A., Palaiologou, P., Evers, C.R., Day, M.A., and Barros, A.M.G., 2018, Assessing transboundary wildfire exposure in the southwestern United States: Risk Analysis, v. 38, no. 10, p. 2105–2127, at https://doi.org/10.1111/risa.12999. |
Tradeoffs between US national forest harvest targets and fuel management to reduce wildfire transmission to the wildland urban interface | A. A. Ager, R. M. Houtman, M. A. Day, C. Ringo, P. Palaiologou | 2019 | Ager, A.A., Houtman, R.M., Day, M.A., Ringo, C., and Palaiologou, P., 2019, Tradeoffs between US national forest harvest targets and fuel management to reduce wildfire transmission to the wildland urban interface: Forest Ecology and Management, v. 434, p. 99–109, at https://doi.org/10.1016/j.foreco.2018.12.003. |
Planning for future fire—Scenario analysis of an accelerated fuel reduction plan for the western United States | A. A. Ager, C. R. Evers, M. A. Day, F. J. Alcasena, R. Houtman | 2021a | Ager, A.A., Evers, C.R., Day, M.A., Alcasena, F.J., and Houtman, R., 2021a, Planning for future fire—Scenario analysis of an accelerated fuel reduction plan for the western United States: Landscape and Urban Planning, v. 215, article 104212, at https://doi.org/10.1016/j.landurbplan.2021.104212. |
Predicting paradise—Modeling future wildfire disasters in the western US | A. A. Ager, M. A. Day, F. J. Alcasena, C. R. Evers, K. C. Short, I. Grenfell | 2021b | Ager, A.A., Day, M.A., Alcasena, F.J., Evers, C.R., Short, K.C., and Grenfell, I., 2021b, Predicting paradise—Modeling future wildfire disasters in the western US: Science of the Total Environment, v. 784, article 147057, at https://doi.org/10.1016/j.scitotenv.2021.147057. |
Analyzing fine-scale spatiotemporal drivers of wildfire in a forest landscape model | A. A. Ager, A. M. G. Barros, M. A. Day, H. K. Preisler, T. A. Spies, J. Bolte | 2018 | Ager, A.A., Barros, A.M.G., Day, M.A., Preisler, H.K., Spies, T.A., and Bolte, J., 2018, Analyzing fine-scale spatiotemporal drivers of wildfire in a forest landscape model: Ecological Modelling, v. 384, p. 87–102, at https://doi.org/10.1016/j.ecolmodel.2018.06.018. |
Contrasting effects of future wildfire and forest management scenarios on a fire excluded western US landscape | A. A. Ager, A. M. G. Barros, M. A. Day | 2022 | Ager, A.A., Barros, A.M.G., and Day, M.A., 2022, Contrasting effects of future wildfire and forest management scenarios on a fire excluded western US landscape: Landscape Ecology, v. 37, no. 4, p. 1091–1112, at https://doi.org/10.1007/s10980-022-01414-y. |
Model-assisted domain estimation of postfire tree regeneration in the western US using nearest neighbor techniques | D. L. R. Affleck, G. C. Gaines | 2023 | Affleck, D.L.R., and Gaines, G.C., 2023, Model-assisted domain estimation of postfire tree regeneration in the western US using nearest neighbor techniques: Canadian Journal of Forest Research, v. 53, no. 12, p. 981–995, at https://doi.org/10.1139/cjfr-2023-0007. |
Soil carbon pools and fluxes vary across a burn severity gradient three years after wildfire in Sierra Nevada mixed-conifer forest | J. Adkins, J. Sanderman, J. Miesel | 2019 | Adkins, J., Sanderman, J., and Miesel, J., 2019, Soil carbon pools and fluxes vary across a burn severity gradient three years after wildfire in Sierra Nevada mixed-conifer forest: Geoderma, v. 333, p. 10–22, at https://doi.org/10.1016/j.geoderma.2018.07.009. |
Copiotrophic bacterial traits increase with burn severity one year after a wildfire | J. Adkins, K. M. Docherty, J. R. Miesel | 2022 | Adkins, J., Docherty, K.M., and Miesel, J.R., 2022, Copiotrophic bacterial traits increase with burn severity one year after a wildfire: Frontiers in Forests and Global Change, v. 5, article 873527, at https://doi.org/10.3389/ffgc.2022.873527. |
How do soil microbial communities respond to fire in the intermediate term? Investigating direct and indirect effects associated with fire occurrence and burn severity | J. Adkins, K. M. Docherty, J. L. M. Gutknecht, J. R. Miesel | 2020 | Adkins, J., Docherty, K.M., Gutknecht, J.L.M., and Miesel, J.R., 2020, How do soil microbial communities respond to fire in the intermediate term? Investigating direct and indirect effects associated with fire occurrence and burn severity: Science of the Total Environment, v. 745, article 140957, at https://doi.org/10.1016/j.scitotenv.2020.140957. |
Fire?produced coarse woody debris and its role in sediment storage on hillslopes | K. V. Adams, J. L. Dixon, A. C. Wilcox, D. McWethy | 2023 | Adams, K.V., Dixon, J.L., Wilcox, A.C., and McWethy, D., 2023, Fire?produced coarse woody debris and its role in sediment storage on hillslopes: Earth Surface Processes and Landforms, v. 48, no. 9, p. 1665–1678, at https://doi.org/10.1002/esp.5573. |
Asymmetric hillslope erosion following wildfire in Fourmile Canyon, Colorado | E. R. Abrahams, J. M. Kaste, W. Ouimet, D. P. Dethier | 2018 | Abrahams, E.R., Kaste, J.M., Ouimet, W., and Dethier, D.P., 2018, Asymmetric hillslope erosion following wildfire in Fourmile Canyon, Colorado: Earth Surface Processes and Landforms, v. 43, no. 9, p. 2009–2021, at https://doi.org/10.1002/esp.4348. |
Winter and spring climate explains a large portion of interannual variability and trend in western US summer fire burned area | R. Abolafia-Rosenzweig, C. L. He, F. Chen | 2022 | Abolafia-Rosenzweig, R., He, C.L., and Chen, F., 2022, Winter and spring climate explains a large portion of interannual variability and trend in western US summer fire burned area: Environmental Research Letters, v. 17, no. 5, article 054030, at https://doi.org/10.1088/1748-9326/ac6886. |
Impact of anthropogenic climate change on wildfire across western US forests | J. T. Abatzoglou, A. P. Williams | 2016 | Abatzoglou, J.T., and Williams, A.P., 2016, Impact of anthropogenic climate change on wildfire across western US forests: Proceedings of the National Academy of Sciences of the United States of America, v. 113, no. 42, p. 11770–11775, at https://doi.org/10.1073/pnas.1607171113. |
Climatic influences on interannual variability in regional burn severity across western US forests | J. T. Abatzoglou, C. A. Kolden, A. P. Williams, J. A. Lutz, A. M. S. Smith | 2017 | Abatzoglou, J.T., Kolden, C.A., Williams, A.P., Lutz, J.A., and Smith, A.M.S., 2017, Climatic influences on interannual variability in regional burn severity across western US forests: International Journal of Wildland Fire, v. 26, no. 4, p. 269–275, at https://doi.org/10.1071/WF16165. |
Relationships between climate and macroscale area burned in the western United States | J. T. Abatzoglou, C. A. Kolden | 2013 | Abatzoglou, J.T., and Kolden, C.A., 2013, Relationships between climate and macroscale area burned in the western United States: International Journal of Wildland Fire, v. 22, no. 7, p. 1003–1020, at https://doi.org/10.1071/WF13019. |
Increasing synchronous fire danger in forests of the western United States | J. T. Abatzoglou, C. S. Juang, A. P. Williams, C. A. Kolden, A. L. Westerling | 2021 | Abatzoglou, J.T., Juang, C.S., Williams, A.P., Kolden, C.A., and Westerling, A.L., 2021, Increasing synchronous fire danger in forests of the western United States: Geophysical Research Letters, v. 48, no. 2, article e2020GL091377, at https://doi.org/10.1029/2020GL091377. |
Projected increases in western US forest fire despite growing fuel constraints | J. T. Abatzoglou, D. S. Battisti, A. P. Williams, W. D. Hansen, B. J. Harvey, C. A. Kolden | 2021 | Abatzoglou, J.T., Battisti, D.S., Williams, A.P., Hansen, W.D., Harvey, B.J., and Kolden, C.A., 2021, Projected increases in western US forest fire despite growing fuel constraints: Communications Earth & Environment, v. 2, no. 1, article 227, at https://doi.org/10.1038/s43247-021-00299-0. |
Title | Authors | Year | Citation |
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Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the United States | Zhu, Z., ed.,, Bouchard, M., Butman, D., Hawbaker, T., Li, Z., Liu, J., Liu, S., McDonald, C., Reker, R., Sayler, K., Sleeter, B., Sohl, T., Stackpoole, S., Wein, A., Zhu, Z. | 2011 | Zhu, Z., ed.,, Bouchard, M., Butman, D., Hawbaker, T., Li, Z., Liu, J., Liu, S., McDonald, C., Reker, R., et al., 2011, Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the United States: Reston, Va., U.S. Geological Survey Professional Paper 1787, 40 p., at https://doi.org/10.3133/pp1787. |
Wildfire risk and urban expansion in South Kohala and North Kona, Hawaiʻi—Assessing new and existing areas of wildfire risk in relation to Hawaiʻi’s fire history, land cover, and tree canopy, through the lens of urban expansion | Yee, C. | 2024 | Yee, C., 2024, Wildfire risk and urban expansion in South Kohala and North Kona, Hawaiʻi—Assessing new and existing areas of wildfire risk in relation to Hawaiʻi’s fire history, land cover, and tree canopy, through the lens of urban expansion: Kaulunani, Hawaiʻi, Kaulunani Urban and Community Forestry Program of the DLNR Division of Forestry and Wildlife, and State and Private Forestry, branch of the U.S. Forest Service, Region 5 Technical Report, 17 p., at https://dlnr.hawaii.gov/forestry/files/2024/03/Yee_TechnicalReport.pdf. |
Abducted by avians—The presence of avifauna in piñon-juniper woodlands in the post-fire environment, Final Report | Woolet, J., Stevens-Rumann, C. | 2022 | Woolet, J., and Stevens-Rumann, C., 2022, Abducted by avians—The presence of avifauna in piñon-juniper woodlands in the post-fire environment, Final Report: Joint Fire Science Program JFSP PROJECT ID—21-1-01-36, 40 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%27%3AV%20%20%20%0A. |
Impacts of burn severity, microclimate, and soil properties on initial post-fire tree regeneration, Final Report | Wolf, K.D., Higuera, P.E., Davis, K.T. | 2021 | Wolf, K.D., Higuera, P.E., and Davis, K.T., 2021, Impacts of burn severity, microclimate, and soil properties on initial post-fire tree regeneration, Final Report: Joint Fire Science Program JFSP PROJECT ID—18-1-01-53, 35 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2F4VP%20%20%0A. |
Idaho’s forest resources, 2004–2009 | Witt, C., Shaw, J. D., Thompson, M. T., Goeking, S. A., Menlove, J., Amacher, M. C., Morgan, T. A., Werstak, C. | 2012 | Witt, C., Shaw, J.D., Thompson, M.T., Goeking, S.A., Menlove, J., Amacher, M.C., Morgan, T.A., and Werstak, C., 2012, Idaho’s forest resources, 2004–2009: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-14, 134 p., at https://doi.org/10.2737/RMRS-RB-14. |
Recurrent managed wildfire buffers trees from the effects of multiyear drought events, Final Report | Willson, K.G., Hurteau, M.D. | 2023 | Willson, K.G., and Hurteau, M.D., 2023, Recurrent managed wildfire buffers trees from the effects of multiyear drought events, Final Report: Joint Fire Science Program JFSP PROJECT ID—21-1-01-31, 29 p., at https://www.firescience.gov/projects/21-1-01-31/project/21-1-01-31_final_report.pdf. |
Wildfire simulations for California’s fourth climate change assessment—Projecting changes in extreme wildfire events with a warming climate, California’s Fourth Climate Change Assessment | Westerling, A.L. | 2018 | Westerling, A.L., 2018, Wildfire simulations for California’s fourth climate change assessment—Projecting changes in extreme wildfire events with a warming climate, California’s Fourth Climate Change Assessment: California Energy Commission CCCA4-CEC-2018014, 57 p., at https://climateassessment.ca.gov/techreports/projections-datasets.html. |
Utah’s forest resources, 2003–2012 | Werstak, C. E., Jr., Shaw, J. D., Goeking, S. A., Witt, C., Menlove, J., Thompson, M. T., Derose, R. J., Amacher, M. C., Jovan, S., Morgan, T. A., Sorenson, C. B., Hayes, S. W., McIver, C. P. | 2016 | Werstak, C.E., Jr., Shaw, J.D., Goeking, S.A., Witt, C., Menlove, J., Thompson, M.T., Derose, R.J., Amacher, M.C., Jovan, S., et al., 2016, Utah’s forest resources, 2003–2012: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-20, 159 p., at https://doi.org/10.2737/RMRS-RB-20. |
How local are the local economic impacts of wildfires? | Walls, M.A., Wibbenmeyer, M. | 2023 | Walls, M.A., and Wibbenmeyer, M., 2023, How local are the local economic impacts of wildfires?: Washington, D.C., Resources for the Future Working Paper 23-03, 38 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-23-03. |
Modeling the influence of climate and local site factors on post-fire regeneration in the Southern Rocky Mountains, Final Report | Veblen, T., Rodman, K. | 2019 | Veblen, T., and Rodman, K., 2019, Modeling the influence of climate and local site factors on post-fire regeneration in the Southern Rocky Mountains, Final Report: Joint Fire Science Program JFSP PROJECT ID—17-2-01-4, 32 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JK%3FV%20%20%20%0A. |
Potential postwildfire debris-flow hazards—A prewildfire evaluation for the Jemez Mountains, north-central New Mexico | Tillery, Anne C., Haas, Jessica R. | 2016 | Tillery, A.C., and Haas, J.R., 2016, Potential postwildfire debris-flow hazards—A prewildfire evaluation for the Jemez Mountains, north-central New Mexico: Reston, Va., U.S. Geological Survey Scientific-Investigations Report 2016-5101, 27 p., at https://doi.org/10.3133/sir20165101. |
Colorado’s forest resources, 2004–2013 | Thompson, M. T., Shaw, J. D., Witt, C., Werstak, C. E., Jr., Amacher, M. C., Goeking, S. A., DeRose, R. J., Morgan, T. A., Sorenson, C. B., Hayes, S. W., Menlove, J. | 2017 | Thompson, M.T., Shaw, J.D., Witt, C., Werstak, C.E., Jr., Amacher, M.C., Goeking, S.A., DeRose, R.J., Morgan, T.A., Sorenson, C.B., et al., 2017, Colorado’s forest resources, 2004–2013: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-23, 136 p., at https://doi.org/10.2737/RMRS-RB-23. |
Effects of wildfires and fuel treatment strategies on watershed water quantity across the contiguous United States, Final Report | Sun, G., Hallema, D.W., Cohen, E.C., McNulty, S.G., Caldwell, P.V., Robinne, F.-N., Norman, S.P., Liu, Y. | 2019 | Sun, G., Hallema, D.W., Cohen, E.C., McNulty, S.G., Caldwell, P.V., Robinne, F.-N., Norman, S.P., and Liu, Y., 2019, Effects of wildfires and fuel treatment strategies on watershed water quantity across the contiguous United States, Final Report: Joint Fire Science Program JFSP PROJECT ID—14-1-06-18, 147 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%3F%3CW0%20%20%0A. |
Grassland, forest and riparian ecosystems on mixed-ownership federal lands adjacent to the Crow Indian Reservation—Developing a protective shield for sustainability of the environment and culture from the impacts of climate-related disturbance | Stumpff, Linda M., Sanchez-Trigueros, Fernando, Watson, Alan E., Mdodi, Florence, Teasdale, Aaron | 2020 | Stumpff, L.M., Sanchez-Trigueros, F., Watson, A.E., Mdodi, F., and Teasdale, A., 2020, Grassland, forest and riparian ecosystems on mixed-ownership federal lands adjacent to the Crow Indian Reservation—Developing a protective shield for sustainability of the environment and culture from the impacts of climate-related disturbance: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-410, 84 p., at https://www.fs.usda.gov/treesearch/pubs/59871. |
Guidebook on LANDFIRE fuels data acquisition, critique, modification, maintenance, and model calibration | Stratton, R. D. | 2009 | Stratton, R.D., 2009, Guidebook on LANDFIRE fuels data acquisition, critique, modification, maintenance, and model calibration: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-220, 60 p., at https://doi.org/10.2737/RMRS-GTR-220. |
Assessing post-wildfire conifer regeneration—Validation of a non-destructive seedling aging method, Final Report | Strand, E.K., Hammond, D.H. | 2019 | Strand, E.K., and Hammond, D.H., 2019, Assessing post-wildfire conifer regeneration—Validation of a non-destructive seedling aging method, Final Report: Joint Fire Science Program JFSP PROJECT ID—17-2-01-11, 22 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JK%3AV%20%20%20%0A. |
Arizona’s forest resources, 2001–2014 | Shaw, J. D., Menlove, J., Witt, C., Morgan, T. A., Amacher, M. C., Goeking, S. A., Werstak, C. E., Jr. | 2018 | Shaw, J.D., Menlove, J., Witt, C., Morgan, T.A., Amacher, M.C., Goeking, S.A., and Werstak, C.E., Jr., 2018, Arizona’s forest resources, 2001–2014: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-25, 126 p., at https://www.fs.usda.gov/treesearch/pubs/56264. |
Establishing a nationwide baseline of historical burn-severity data to support monitoring of trends in wildfire effects and national fire policies | Schwind, Brian, Brewer, Ken, Quayle, Brad, Eidenshink, Jeffery C. | 2010 | Schwind, B., Brewer, K., Quayle, B., and Eidenshink, J.C., 2010, Establishing a nationwide baseline of historical burn-severity data to support monitoring of trends in wildfire effects and national fire policies, in Pye, J.M., Rauscher, H.M., Sands, Y., Lee, D.C., and Beatty, J.S., eds., Advances in threat assessment and their application to forest and rangeland management: Portland, Oreg., U.S. Forest Service, Pacific Northwest and Southern Research Station Gen. Tech. Rep. PNW-GTR-802, p. 381–396, at https://www.fs.usda.gov/research/treesearch/37081. |
Seedlings? The unexpected elders of understory trees, Final Report | Zoe Schapira, Camille Stevens-Rumann | 2020 | Schapira, Z., and Stevens-Rumann, C., 2020, Seedlings? The unexpected elders of understory trees, Final Report: Joint Fire Science Program JFSP PROJECT ID—19-1-01-59, 19 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2B9W0%20%20%0A. |
Wildland fire in Wyoming—Patterns, influences, and effects | Scasta, D. | 2015 | Scasta, D., 2015, Wildland fire in Wyoming—Patterns, influences, and effects: Laramie, Wyo., University of Wyoming B-1271, 26 p., at https://www.wyoextension.org/publications/Search_Details.php?pubid=1882. |
Postwildfire measurement of soil physical and hydraulic properties at selected sampling sites in the 2011 Las Conchas wildfire burn scar, Jemez Mountains, north-central New Mexico | Romero, Orlando C., Ebel, Brian A., Martin, Deborah A., Buchan, Katie W., Jornigan, Alanna D. | 2018 | Romero, O.C., Ebel, B.A., Martin, D.A., Buchan, K.W., and Jornigan, A.D., 2018, Postwildfire measurement of soil physical and hydraulic properties at selected sampling sites in the 2011 Las Conchas wildfire burn scar, Jemez Mountains, north-central New Mexico: Reston, Va., U.S. Geological Survey Scientific Investigations Report 2018–5028, 48 p., at https://doi.org/10.3133/sir20185028. |
Climate adaptation | Remington, Thomas E., Deibert, Patricia A., Hanser, Steve E., Davis, Dawn M., Robb, Leslie A., Welty, Justin L. | 2021 | Remington, T.E., Deibert, P.A., Hanser, S.E., Davis, D.M., Robb, L.A., and Welty, J.L., 2021, Climate adaptation, in Remington, T.E., Deibert, P.A., Hanser, S.E., Davis, D.M., Robb, L.A., and Welty, J.L., eds., Sagebrush conservation strategy—Challenges to sagebrush conservation: Reston, Va., U.S. Geological Survey Open-File Report 2020-1125, p. 121–137, at https://doi.org/10.3133/ofr20201125. |
A novel approach for estimating nonforest carbon stocks in support of forest plan revision | Reeves, M.C., Hanberry, B., Bruggink, J.L., Krebs, M.A., Campbell, S.B., Baggett, L. S. | 2020 | Reeves, M.C., Hanberry, B., Bruggink, J.L., Krebs, M.A., Campbell, S.B., and Baggett, L.S., 2020, A novel approach for estimating nonforest carbon stocks in support of forest plan revision Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Res. Note RMRS-RN-86, 20 p., at https://www.fs.usda.gov/treesearch/pubs/60860. |
Evaluating the influence of prior burn mosaics on subsequent wildfire behavior, severity, and fire management options, Final Report | Prichard, S., Hessburg, P. F., Gray, R., Povak, N. A., Salter, R.B., Stevens-Rumann, C., Morgan, P. | 2018 | Prichard, S., Hessburg, P.F., Gray, R., Povak, N.A., Salter, R.B., Stevens-Rumann, C., and Morgan, P., 2018, Evaluating the influence of prior burn mosaics on subsequent wildfire behavior, severity, and fire management options, Final Report: Joint Fire Science Program JFSP PROJECT ID—14-1-02-30, 51 p., at https://www.frames.gov/catalog/56784. |
Grand Valley ecological forecasting—Assessing trends in pinyon-juniper habitat relative to drought, beetle infestation, wildland fires, and treatment to plan future management strategies | Powers, G., Stone, E., Arowoogun, K., Tree, M. | 2022 | Powers, G., Stone, E., Arowoogun, K., and Tree, M., 2022, Grand Valley ecological forecasting—Assessing trends in pinyon-juniper habitat relative to drought, beetle infestation, wildland fires, and treatment to plan future management strategies: Pocatello, Idaho, NASA DEVELOP National Program NASA DEVELOP Technical Report, Final Draft – March 31st , 2022, 22 p., at https://giscenter.isu.edu/research/Techpg/nasa_DEVELOP/pdf/2022Spring_ID_GrandValleyEco_TechPaper_FD-final.pdf. |
Priorities and effectiveness in wildfire management—Evidence from fire spread in the western United States | Plantinga, Andrew J., Walsh, Randall, Wibbenmeyer, Matthew | 2020 | Plantinga, A.J., Walsh, R., and Wibbenmeyer, M., 2020, Priorities and effectiveness in wildfire management—Evidence from fire spread in the western United States: Washington, D.C., Resources for the Future, 47 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-20-21. |
Quantifying the risk of fire-facilitated transition to non-forest in California and the Southwest, Final Report | Parks, S.A., Dobrowski, S.Z., Shaw, J.D., Miller, C. | 2019 | Parks, S.A., Dobrowski, S.Z., Shaw, J.D., and Miller, C., 2019, Quantifying the risk of fire-facilitated transition to non-forest in California and the Southwest, Final Report: Joint Fire Science Program JFSP PROJECT ID—15-1-03-20, 37 p., at https://www.frames.gov/catalog/57635. |
LANDFIRE 2010—Updates to the national dataset to support improved fire and natural resource management | Nelson, Kurtis J., Long, Donald G., Connot, Joel A. | 2016 | Nelson, K.J., Long, D.G., and Connot, J.A., 2016, LANDFIRE 2010—Updates to the national dataset to support improved fire and natural resource management: Reston, Va., U.S. Geological Survey Open-File Report 2016-1010, 59 p., at https://doi.org/10.3133/ofr20161010. |
Grounded—An enterprise-wide look at Department of the Air Force installation exposure to natural hazards, Implications for infrastructure investment decisionmaking and continuity of operations planning | Narayanan, Anu, Lostumbo, Michael J., Van Abel, Kristin, Wilson, Michael T., Wirth, Anna Jean, Rahim, Ali | 2021 | Narayanan, A., Lostumbo, M.J., Van Abel, K., Wilson, M.T., Wirth, A.J., and Rahim, A., 2021, Grounded—An enterprise-wide look at Department of the Air Force installation exposure to natural hazards, Implications for infrastructure investment decisionmaking and continuity of operations planning: Santa Monica, Calif., Rand Corporation RR-A523-1, 146 p., at https://www.rand.org/pubs/research_reports/RRA523-1.html. |
A fuelscape for all-lands in Utah | Napoli, J., Gilbertson-Day, J.W., Scott, J.H. | 2022 | Napoli, J., Gilbertson-Day, J.W., and Scott, J.H., 2022, A fuelscape for all-lands in Utah: Utah Department of Natural Resources, Division of Forestry, Fire and State Lands, 23 p., at https://pyrologix.com/reports/Utah_FuelscapeReport.pdf. |
Northwest Forest Plan—The first 15 years (1994–2008)—Status and trends of late-successional and old-growth forests | Moeur, M., Ohmann, J. L., Kennedy, R. E., Cohen, W. B., Gregory, M. J., Yang, Z., Roberts, H. M., Spies, T. A., Fiorella, M. | 2011 | Moeur, M., Ohmann, J.L., Kennedy, R.E., Cohen, W.B., Gregory, M.J., Yang, Z., Roberts, H.M., Spies, T.A., and Fiorella, M., 2011, Northwest Forest Plan—The first 15 years (1994–2008)—Status and trends of late-successional and old-growth forests: Portland, Oreg., U.S. Forest Service, Pacific Northwest Research Station Gen. Tech. Rep. PNW-GTR-853, 48 p., at https://doi.org/10.2737/PNW-GTR-853. |
Greater sage-grouse habitat of Nevada and northeastern California—Integrating space use, habitat selection, and survival indices to guide areas for habitat management | Milligan, M.C., Coates, P.S., O’Neil, S.T., Brussee, B.E., Chenaille, M.P., Friend, D., Steele, K., Small, J.R., Bowden, T.S., Kosic, A.D., Miller, K. | 2024 | Milligan, M.C., Coates, P.S., O’Neil, S.T., Brussee, B.E., Chenaille, M.P., Friend, D., Steele, K., Small, J.R., Bowden, T.S., et al., 2024, Greater sage-grouse habitat of Nevada and northeastern California—Integrating space use, habitat selection, and survival indices to guide areas for habitat management: Reston, Va., U.S. Geological Survey Open-File Report 2024–1018, 70 p., at https://doi.org/10.3133/ofr20241018. |
Nevada’s forest resources, 2004–2013 | Menlove, J., Shaw, J. D., Witt, C., Werstak, C. E., Jr., Justin DeRose, R., Goeking, S. A., Amacher, M. C., Morgan, T. A., Sorenson, C. B. | 2016 | Menlove, J., Shaw, J.D., Witt, C., Werstak, C.E., Jr., Justin DeRose, R., Goeking, S.A., Amacher, M.C., Morgan, T.A., and Sorenson, C.B., 2016, Nevada’s forest resources, 2004–2013: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-22, 167 p., at https://doi.org/10.2737/RMRS-RB-22. |
Montana’s forest resources, 2003–2009 | Menlove, J., Shaw, J. D., Thompson, M. T., Witt, C., Amacher, M. C., Morgan, T. A., Sorenson, C., McIver, C., Werstak, C. | 2012 | Menlove, J., Shaw, J.D., Thompson, M.T., Witt, C., Amacher, M.C., Morgan, T.A., Sorenson, C., McIver, C., and Werstak, C., 2012, Montana’s forest resources, 2003–2009: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-15, 140 p., at https://doi.org/10.2737/RMRS-RB-15. |
Black Hills wildfires mapping post-fire conifer regeneration using snow-on imagery | Menick, C., Seldon, Y., Stuckmeyer, H., Rogers, H. | 2022 | Menick, C., Seldon, Y., Stuckmeyer, H., and Rogers, H., 2022, Black Hills wildfires mapping post-fire conifer regeneration using snow-on imagery: Fort Collins, Colo., NASA DEVELOP National Program NASA DEVELOP Technical Report, 14 p., at https://ntrs.nasa.gov/api/citations/20220014676/downloads/2022Sum_CO_BlackHillsWildfires_TechPaper_FD-final.docx.pdf. |
Effects of wildfire destruction on migration, consumer credit, and financial distress | McConnell, Kathryn, Whitaker, Stephan D., Fussell, Elizabeth, DeWaard, Jack, Curtis, Katherine, Price, Kobie, St. Denis, Lise, Balch, Jennifer | 2021 | McConnell, K., Whitaker, S.D., Fussell, E., DeWaard, J., Curtis, K., Price, K., St. Denis, L., and Balch, J., 2021, Effects of wildfire destruction on migration, consumer credit, and financial distress: Federal Reserve Bank of Cleveland Working Paper No. 21-29, 58 p., at https://doi.org/10.26509/frbc-wp-202129. |
Risk disclosure and home prices—Evidence from California wildfire hazard zones | Ma, L., Walls, M., Wibbenmeyer, M., Lennon, C. | 2023 | Ma, L., Walls, M., Wibbenmeyer, M., and Lennon, C., 2023, Risk disclosure and home prices—Evidence from California wildfire hazard zones: Washington, D.C., Resources for the Future Working Paper 23-26, 36 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-23-26. |
Status and trend of nesting habitat for the Marbled Murrelet under the Northwest Forest Plan, 1993 to 2017 | Lorenz, T.J., Raphael, M.G., Young, R.D., Lynch, D., Nelson, S.K., McIver, W.R. | 2021 | Lorenz, T.J., Raphael, M.G., Young, R.D., Lynch, D., Nelson, S.K., and McIver, W.R., 2021, Status and trend of nesting habitat for the Marbled Murrelet under the Northwest Forest Plan, 1993 to 2017: Portland, Oreg., U.S. Forest Service, Pacific Northwest Research Station Gen. Tech. Rep. PNW-GTR-998, 64 p., at https://www.fs.usda.gov/pnw/publications/status-and-trend-nesting-habitat-marbled-murrelet-under-northwest-forest-plan-1993-2017. |
Landscape evaluations and prescriptions for post-fire landscapes, Final Report | Larson, A.J., Cansler, C.A., Kane, V.R., Churchill, D.J., Hessburg, P.F., Lutz, J.A., Povak, N.A. | 2020 | Larson, A.J., Cansler, C.A., Kane, V.R., Churchill, D.J., Hessburg, P.F., Lutz, J.A., and Povak, N.A., 2020, Landscape evaluations and prescriptions for post-fire landscapes, Final Report: Joint Fire Science Program JFSP PROJECT ID—16-1-05-24, 56 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JO%3AT0%20%20%0A. |
Influence of past wildfires on wildfire effects in northern Rockies mixed-conifer forest, Final Report | Larson, A. J., Belote, R. T. | 2018 | Larson, A.J., and Belote, R.T., 2018, Influence of past wildfires on wildfire effects in northern Rockies mixed-conifer forest, Final Report: Joint Fire Science Program, JFSP PROJECT ID—14-1-02-9, 50 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%234V%40%20%20%0A. |
Integrated modeling and assessment of North American forest carbon dynamics technical report—Tools for monitoring, reporting and projecting forest greenhouse gas emissions and removals | Kurz, W.A., Birdsey, R.A., Mascorro, V.S., Greenberg, D., Dai, Z., Olguin, M., Colditz, R. | 2016 | Kurz, W.A., Birdsey, R.A., Mascorro, V.S., Greenberg, D., Dai, Z., Olguin, M., and Colditz, R., 2016, Integrated modeling and assessment of North American forest carbon dynamics technical report—Tools for monitoring, reporting and projecting forest greenhouse gas emissions and removals: Montreal, Canada, Commission for Environmental Cooperation, 125 p., at https://www3.cec.org/islandora/en/item/11655-integrated-modeling-and-assessment-north-american-forest-carbon-dynamics. |
Vegetation succession in an old-growth ponderosa pine forest following structural restoration with fire—Implications for retreatment and maintenance, Final Report | Knapp, E. , Taylor, A., Coppoletta, M., Pawlikowski, N. | 2019 | Knapp, E., Taylor, A., Coppoletta, M., and Pawlikowski, N., 2019, Vegetation succession in an old-growth ponderosa pine forest following structural restoration with fire—Implications for retreatment and maintenance, Final Report: Joint Fire Science Program JFSP PROJECT ID—15-07-1-19, 34 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J79T%20%20%20%0A. |
Guadalupe Mountains National Park—Natural resource condition assessment | Kilkus, K., Nadeau, A.J., Amberg, S., Gardner, S., Komp, M.R., Drazkowski, B., Myers, M. | 2013 | Kilkus, K., Nadeau, A.J., Amberg, S., Gardner, S., Komp, M.R., Drazkowski, B., and Myers, M., 2013, Guadalupe Mountains National Park—Natural resource condition assessment: Fort Collins, Colo., U.S. National Park Service Natural Resource Report NPS/GUMO/NRR—2013/668, 328 p., at https://www.nps.gov/orgs/1439/nrca_gumo.htm. |
Advancing post-fire tree mortality models to limit fire-induced oak mortality, Final Report | Kane, J.M., Jones, A.M. | 2021 | Kane, J.M., and Jones, A.M., 2021, Advancing post-fire tree mortality models to limit fire-induced oak mortality, Final Report Joint Fire Science Program JFSP PROJECT ID—20-1-01-10, 28 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2B4W0%20%20%0A. |
Wildfire in Utah—The physical and economic consequences of wildfire | Jakus, P.M, Kim, M.-K., Margin, R.C., Hammond, I., Hammill, E., Mesner, N. | 2017 | Jakus, P.M., Kim, M.-K., Margin, R.C., Hammond, I., Hammill, E., and Mesner, N., 2017, Wildfire in Utah—The physical and economic consequences of wildfire: Logan, Utah, Utah State University, Watershed Sciences Faculty Publications, Paper 1002, 200 p., at https://digitalcommons.usu.edu/wats_facpub/1002. |
Effects of changing wildfire management strategies, Final Report | Iniguez, J., Thode, A., McCaffrey, S., Evans, A., Meyer, M., Hedwall, S. | 2021 | Iniguez, J., Thode, A., McCaffrey, S., Evans, A., Meyer, M., and Hedwall, S., 2021, Effects of changing wildfire management strategies, Final Report: Joint Fire Science Program JFSP PROJECT ID—17-01-03, 42 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JK4V%40%20%20%0A. |
How vegetation recovery and fuel conditions in past fires influences fuels and future fire management in five western U.S. ecosystems, Final Report | Hudak, A. T., Newingham, B. A., Strand, E. K., Morgan, P. | 2018 | Hudak, A.T., Newingham, B.A., Strand, E.K., and Morgan, P., 2018, How vegetation recovery and fuel conditions in past fires influences fuels and future fire management in five western U.S. ecosystems, Final Report: Joint Fire Science Program JFSP PROJECT ID—14-1-02-27, 33 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%3F5W0%20%20%0A. |
Mortality reconsidered—Testing and extending models of fire-induced tree mortality across the US, Final Project Summary | Hood, S.M., Varner, J.M., Cansler, C.A. | 2019 | Hood, S.M., Varner, J.M., and Cansler, C.A., 2019, Mortality reconsidered—Testing and extending models of fire-induced tree mortality across the US, Final Project Summary: Joint Fire Science Program JFSP PROJECT ID—16-1-04-8, 40 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JO4WP%20%20%0A. |
Predicting fire-mediated forest structure over biophysical gradients in moist mixed conifer forests, Final Report | Holz, A., Platt, L., Kemp, K. , Naficy, C. | 2021 | Holz, A., Platt, L., Kemp, K., and Naficy, C., 2021, Predicting fire-mediated forest structure over biophysical gradients in moist mixed conifer forests, Final Report: Joint Fire Science Program JFSP PROJECT ID—19-1-01-49, 33 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2B%3FT0%20%20%0A. |
Post-fire water quality—An investigation of determinants and recovery processes in burned watersheds across the western U.S., Final Report | Hogue, T.S., McCray, J. | 2019 | Hogue, T.S., and McCray, J., 2019, Post-fire water quality—An investigation of determinants and recovery processes in burned watersheds across the western U.S., Final Report: Joint Fire Science Program JFSP PROJECT ID—14-1-06-14, 47 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26J%234T0%20%20%0A. |
Wildland fires and greenhouse gas emissions in Hawai‘i | Hawbaker, T.J., Trauernicht, C., Howard, S.M., Litton, C.M., Giardina, C.P., Jacobi, J.D., Fortini, L.B., Hughes, R.F., Selmants, P.C., Zhu, Z. | 2017 | Hawbaker, T.J., Trauernicht, C., Howard, S.M., Litton, C.M., Giardina, C.P., Jacobi, J.D., Fortini, L.B., Hughes, R.F., Selmants, P.C., and Zhu, Z., 2017, Wildland fires and greenhouse gas emissions in Hawai‘i, in Selmants, P.C., Giardina, C.P., Jacobi, J.D., and Zhu, Z., eds., Baseline and projected future carbon storage and carbon fluxes in ecosystems of Hawai‘i: Reston, Va., U.S. Geological Survey Professional Paper 1834, p. 57–73, at https://doi.org/10.3133/pp1834. |
Impacts of multi-year drought on post-fire conifer regeneration in the Inland Northwest, Final Report | Hartter, J., Boag, A. | 2019 | Hartter, J., and Boag, A., 2019, Impacts of multi-year drought on post-fire conifer regeneration in the Inland Northwest, Final Report: Joint Fire Science Program JFSP PROJECT ID—17-2-01-25, 26 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%27%3A%2F%3CW%40%20%20%0A. |
Vegetation climate adaptation planning in support of the Custer Gallatin National Forest Plan revision, Technical Report | Hansen, A.J., Olliff, T., Carnwath, G., Miller, B.W., Hoang, L., Cross, M., Dibenedetto, J., Emmett, K., Keane, R., Kelly, V., Korb, N., Legg, K., Renwick, K, Roberts, D., Thoma, D., Adhikari, A., Belote, T., Dante-Wood, K., Delong, D., Dixon, B., Erdody, T., Laufenberg, D., Soderquist, B. | 2018 | Hansen, A.J., Olliff, T., Carnwath, G., Miller, B.W., Hoang, L., Cross, M., Dibenedetto, J., Emmett, K., Keane, R., et al., 2018, Vegetation climate adaptation planning in support of the Custer Gallatin National Forest Plan revision, Technical Report: Bozeman, Mont., Landscape Biodiversity Lab, Montana State University, 50 p., at https://www.montana.edu/hansenlab/publications.html. |
Climate change vulnerability and adaptation in southwest Oregon | Halofsky, Jessica E., Peterson, David L., Gravenmier, Rebecca A. | 2022 | Halofsky, J.E., Peterson, D.L., and Gravenmier, R.A., 2022, Climate change vulnerability and adaptation in southwest Oregon: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station Gen. Tech. Rep. PNW-GTR-995, 445 p., at https://www.fs.usda.gov/treesearch/pubs/63850. |
Investigating controls of fire frequency on postfire sediment supply, southern California, USA, Final Report | Gray, A.B., Guilinger, J.J. | 2023 | Gray, A.B., and Guilinger, J.J., 2023, Investigating controls of fire frequency on postfire sediment supply, southern California, USA, Final Report: Joint Fire Science Program JFSP PROJECT ID—L20AC0018, 35 p., at https://www.firescience.gov/projects/20-1-01-12/project/20-1-01-12_final_report.pdf. |
New Mexico’s forest resources, 2008–2012 | Goeking, S. A., Shaw, J. D., Witt, C., Thompson, M. T., Werstak Jr, C. E., Amacher, M. C., Stuever, M., Morgan, T. A., Sorenson, C. B., Hayes, S. W., McIver, C. P. | 2014 | Goeking, S.A., Shaw, J.D., Witt, C., Thompson, M.T., Werstak Jr, C.E., Amacher, M.C., Stuever, M., Morgan, T.A., Sorenson, C.B., et al., 2014, New Mexico’s forest resources, 2008–2012: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-18, 156 p., at https://doi.org/10.2737/RMRS-RB-18. |
New Mexico’s forest resources, 2008–2014 | Goeking, S. A., Menlove, J. | 2017 | Goeking, S.A., and Menlove, J., 2017, New Mexico’s forest resources, 2008–2014: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-24, 80 p., at https://doi.org/10.2737/RMRS-RB-24. |
Wildfire, smoke, and outdoor recreation in the western United States | Gellman, J., Walls, M., Wibbenmeyer, M.J. | 2021 | Gellman, J., Walls, M., and Wibbenmeyer, M.J., 2021, Wildfire, smoke, and outdoor recreation in the western United States: Washington, D.C., Resources for the Future Working Paper 21-22, 32 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-21-22. |
Welfare losses from wildfire smoke—Evidence from daily outdoor recreation data | Gellman, J., Walls, M., Wibbenmeyer, M. | 2023 | Gellman, J., Walls, M., and Wibbenmeyer, M., 2023, Welfare losses from wildfire smoke—Evidence from daily outdoor recreation data: Washington, D.C., Resources for the Future Working Paper 23-31, 83 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-23-31. |
Developing a monitoring program for bird populations in the Chiricahua Mountains, Arizona, using citizen observers—Initial stages | Ganey, J.L., Iniguez, J.M., Sanderlin, J.S., Block, W.M. | 2017 | Ganey, J.L., Iniguez, J.M., Sanderlin, J.S., and Block, W.M., 2017, Developing a monitoring program for bird populations in the Chiricahua Mountains, Arizona, using citizen observers—Initial stages: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-368, 30 p., at https://doi.org/10.2737/RMRS-GTR-368. |
Relations among cheatgrass-driven fire, climate, and sensitive status birds across the Great Basin, Final Report | Fleishman, E., Balch, J.K., Bradley, B.A., Horning, N., Leu, M. | 2019 | Fleishman, E., Balch, J.K., Bradley, B.A., Horning, N., and Leu, M., 2019, Relations among cheatgrass-driven fire, climate, and sensitive status birds across the Great Basin, Final Report: Joint Fire Science Program JFSP PROJECT ID—15-1-03-6, 63 p., at https://www.nrfirescience.org/resource/20384. |
Riparian ecosystems of the Manti-La Sal National Forest—An assessment of current conditions in relation to natural range of variability | Driscoll, K.P., Smith, D.M., Finch, D.M. | 2019 | Driscoll, K.P., Smith, D.M., and Finch, D.M., 2019, Riparian ecosystems of the Manti-La Sal National Forest—An assessment of current conditions in relation to natural range of variability: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-386, 160 p., at https://doi.org/10.2737/RMRS-GTR-386. |
Development of a severe fire potential map for the contiguous United States | Dillon, G. K., Panunto, M. H., Davis, B., Morgan, P., Birch, D. S., Jolly, W. M. | 2020 | Dillon, G.K., Panunto, M.H., Davis, B., Morgan, P., Birch, D.S., and Jolly, W.M., 2020, Development of a severe fire potential map for the contiguous United States: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRSGTR-415, 107 p., at https://www.fs.usda.gov/treesearch/pubs/60733. |
Wyoming’s forest resources, 2011–2015 | DeRose, R.J., Shaw, J.D., Goeking,, S.A., Marcille, K., McIver, C.P., Menlove, J., Morgan, T.A., Witt, C. | 2018 | DeRose, R.J., Shaw, J.D., Goeking, S.A., Marcille, K., McIver, C.P., Menlove, J., Morgan, T.A., and Witt, C., 2018, Wyoming’s forest resources, 2011–2015: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Resour. Bull. RMRS-RB-28, 140 p., at https://www.fs.usda.gov/treesearch/pubs/57244. |
2-3-2 cohesive strategy partnership multiparty monitoring plan for the Rio Chama Collaborative Forest Landscape Restoration Program | Dems, C., Cadiente, E., Krasilovsky, E., Kohler, G. | 2023 | Dems, C., Cadiente, E., Krasilovsky, E., and Kohler, G., 2023, 2-3-2 cohesive strategy partnership multiparty monitoring plan for the Rio Chama Collaborative Forest Landscape Restoration Program: 2-3-2 Cohesive Strategy Partnership, 59 p., at https://232partnership.org/wp-content/uploads/2023/04/01_Edition1_MPMplanMain.pdf. |
Northwest Forest Plan—The first 25 years (1994–2018)—Status and trends of northern spotted owl habitats | Davis, Raymond J., Lesmeister, Damon B., Yang, Zhiqiang, Hollen, Bruce, Tuerler, Bridgette, Hobson, Jeremy, Guetterman, John, Stratton, Andrew | 2022 | Davis, R.J., Lesmeister, D.B., Yang, Z., Hollen, B., Tuerler, B., Hobson, J., Guetterman, J., and Stratton, A., 2022, Northwest Forest Plan—The first 25 years (1994–2018)—Status and trends of northern spotted owl habitats: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station Gen. Tech. Rep. PNW-GTR-1003, 38 p., at https://doi.org/10.2737/PNW-GTR-1003. |
Northwest Forest Plan—The first 15 years (1994–2008)—Status and trends of northern spotted owl populations and habitats | Davis, R. J., Dugger, K. M., Mohoric, S., Evers, L., Aney, W. C. | 2011 | Davis, R.J., Dugger, K.M., Mohoric, S., Evers, L., and Aney, W.C., 2011, Northwest Forest Plan—The first 15 years (1994–2008)—Status and trends of northern spotted owl populations and habitats: Portland, Oreg., U.S. Forest Service, Pacific Northwest Research Station Gen. Tech. Rep. PNWGTR-850, 147 p., at https://doi.org/10.2737/PNW-GTR-850. |
Climate variability and post-fire forest regeneration in the Northern Rockies, Final Report | Davis, K.T., Higuera, P.E., Dobrowski, S.Z. | 2021 | Davis, K.T., Higuera, P.E., and Dobrowski, S.Z., 2021, Climate variability and post-fire forest regeneration in the Northern Rockies, Final Report: Joint Fire Science Program JFSP PROJECT ID—16-1-01-15, 27 p., at https://www.firescience.gov/JFSP_advanced_search_results_detail.cfm?jdbid=%24%26JO%3FT0%20%20%0A. |
Retrospective fire modeling—Quantifying the impacts of fire suppression | Davis, B. H., Miller, C., Parks, S. A. | 2010 | Davis, B.H., Miller, C., and Parks, S.A., 2010, Retrospective fire modeling—Quantifying the impacts of fire suppression: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR236WWW, 45 p., at https://doi.org/10.2737/RMRS-GTR-236. |
Marin County wildland fires—Examining fuel load and land cover change to inform fire prevention and suppression decisions in Marin County, CA | Dalal, S., Lee, K., Rosenstein, G., Ross, C. | 2023 | Dalal, S., Lee, K., Rosenstein, G., and Ross, C., 2023, Marin County wildland fires—Examining fuel load and land cover change to inform fire prevention and suppression decisions in Marin County, CA: NASA DEVELOP National Program California – Ames NASA Develop Technical Report, Final, March 30, 2023, 20 p., at https://ntrs.nasa.gov/api/citations/20230006640/downloads/2023Spring_ARC_MarinCountyWildfires_TechPaper_FDv5.pdf?attachment=true. |
Playing with fire—How climate change and development patterns are contributing to the soaring costs of western wildfires | Cleetus, Rachel, Mulik, Kranti | 2014 | Cleetus, R., and Mulik, K., 2014, Playing with fire—How climate change and development patterns are contributing to the soaring costs of western wildfires: Union of Concerned Scientists, 65 p., at https://www.ucsusa.org/resources/playing-fire#ucs-report-downloads. |
Using resilience and resistance concepts to manage threats to sagebrush ecosystems, Gunnison sage-grouse, and greater sage-grouse in their eastern range—A strategic multi-scale approach | Chambers, J. C., Beck, J. L., Campbell, S., Carlson, J., Christiansen, T. J., Clause, K. J., Dinkins, J. B., Doherty, K. E., Griffin, K. A., Havlina, D. W., Henke, K. F., Hennig, J. D., Kurth, L. L., Maestas, J. D., Manning, M., Mayer, K. E., Mealor, B. A., McCarthy, C., Perea, M. A., Pyke, D. A. | 2016 | Chambers, J.C., Beck, J.L., Campbell, S., Carlson, J., Christiansen, T.J., Clause, K.J., Dinkins, J.B., Doherty, K.E., Griffin, K.A., et al., 2016, Using resilience and resistance concepts to manage threats to sagebrush ecosystems, Gunnison sage-grouse, and greater sage-grouse in their eastern range—A strategic multi-scale approach: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-356, 143 p., at https://doi.org/10.2737/RMRS-GTR-356. |
Science framework for conservation and restoration of the sagebrush biome—Linking the Department of the Interior’s Integrated Rangeland Fire Management Strategy to long-term strategic conservation actions. Part 1. Science basis and applications | Chambers, J. C., Beck, J. L., Bradford, J. B., Bybee, J., Campbell, S., Carlson, J., Christiansen, T. J., Clause, K. J., Collins, G., Crist, M. R., Dinkins, J. B., Doherty, K. E., Edwards, F., Espinosa, S., Griffin, K. A., Griffin, P., Haas, J. R., Hanser, S. E., Havlina, D. W., Henke, K. F., Hennig, J. D., Joyce, L. A., Kilkenny, F. F., Kulpa, S. M., Kurth, L. L., Maestas, J. D., Manning, M., Mayer, K. E., Mealor, B. A., McCarthy, C., Pellant, M., Perea, M. A., Prentice, K. L., Pyke, D. A., Wiechman, L. A., Wuenschel, A. | 2017 | Chambers, J.C., Beck, J.L., Bradford, J.B., Bybee, J., Campbell, S., Carlson, J., Christiansen, T.J., Clause, K.J., Collins, G., et al., 2017, Science framework for conservation and restoration of the sagebrush biome—Linking the Department of the Interior’s Integrated Rangeland Fire Management Strategy to long-term strategic conservation actions. Part 1. Science basis and applications: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-360, 213 p., at https://doi.org/10.2737/RMRS-GTR-360. |
Information and tools to restore and conserve Great Basin ecosystems | Chambers, J.C. | 2016 | Chambers, J.C., 2016, Information and tools to restore and conserve Great Basin ecosystems: Reno, Nev., Great Basin Fire Science Exchange Great Basin Factsheet Series 2016, 79 p., at https://www.fs.usda.gov/treesearch/pubs/53208. |
Does high-severity patch structure scale consistently with fire size across the northwest US? Final Report | Buonanduci, M.S., Harvey, B.J. | 2023 | Buonanduci, M.S., and Harvey, B.J., 2023, Does high-severity patch structure scale consistently with fire size across the northwest US? Final Report: Joint Fire Science Program JFSP PROJECT ID—21-1-01-26, 32 p., at https://www.firescience.gov/projects/21-1-01-26/project/21-1-01-26_final_report.pdf. |
Fire patterns in piñon and juniper land cover types in the semiarid western United States from 1984 through 2013 | Board, D.I., Chambers, J.C., Miller, R.F., Weisberg, P.J. | 2018 | Board, D.I., Chambers, J.C., Miller, R.F., and Weisberg, P.J., 2018, Fire patterns in piñon and juniper land cover types in the semiarid western United States from 1984 through 2013: Fort Collins, Colo., U.S. Forest Service, Rocky Mountain Research Station Gen. Tech. Rep. RMRS-GTR-372, 57 p., at https://doi.org/10.2737/RMRS-GTR-372. |
Assessing beaver habitat on federal lands in New Mexico, Final Report | Bird, Bryan, Menke, K., Budrow, D., Hebert, D., Nguyen, A., Roybal, J. | 2013 | Bird, B., Menke, K., Budrow, D., Hebert, D., Nguyen, A., and Roybal, J., 2013, Assessing beaver habitat on federal lands in New Mexico, Final Report: WildEarth Guardians, 23 p., at https://wildearthguardians.org/about-us/research-reports/. |
Mandated vs. voluntary adaptation to natural disasters—The case of U.S. wildfires | Patrick W. Baylis , Judson Boomhower | 2021 | Baylis, P.W., and Boomhower, J., 2021, Mandated vs. voluntary adaptation to natural disasters—The case of U.S. wildfires: National Bureau of Economic Research NBER Working Paper Series, Working Paper 29621, 50 p., at https://www.nber.org/papers/w29621. |
Inequality in agency responsiveness—Evidence from salient wildfire events | Anderson, Sarah, Plantinga, Andrew, Wibbenmeyer, Matthew | 2020 | Anderson, S., Plantinga, A., and Wibbenmeyer, M., 2020, Inequality in agency responsiveness—Evidence from salient wildfire events: Washington, D.C., Resources for the Future Working Paper 20-22, 36 p., at https://EconPapers.repec.org/RePEc:rff:dpaper:dp-20-22. |
Extreme wildfires, distant air pollution, and household financial health | An, Xudong, Gabriel, Stuart, Tzur-Ilan, Nitzan | 2024 | An, X., Gabriel, S., and Tzur-Ilan, N., 2024, Extreme wildfires, distant air pollution, and household financial health: Philadelphia, Pa., Federal Reserve Bank Philadelphia Working Papers Research Department, WP 24-01, 60 p., at https://doi.org/10.21799/frbp.wp.2024.01. |
The race between fuels and fruits—Testing mechanisms of serotinous forest resilience to short-interval severe reburns, Final Report | Agne, M. C., Harvey, B. J. | 2022 | Agne, M.C., and Harvey, B.J., 2022, The race between fuels and fruits—Testing mechanisms of serotinous forest resilience to short-interval severe reburns, Final Report: Joint Fire Science Program JFSP PROJECT ID—19-1-01-16, 32 p., at https://nwcasc.uw.edu/wp-content/uploads/sites/23/2022/04/Agne_Harvey_JFSP_FinalReport.pdf. |
Title | Authors | Year | Citation |
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Forecasting timber, biomass, and tree carbon pools with the output of state and transition models | Zhou, X., Hemstrom, M.A. | 2012 | Zhou, X., and Hemstrom, M.A., 2012, Forecasting timber, biomass, and tree carbon pools with the output of state and transition models, in First Landscape State-and-Transition Simulation Modeling Conference, Portland, Oreg., 14–16 June 2011, Proceedings, General Technical Report PNW-GTR-869: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, p. 115–121, at https://www.treesearch.fs.fed.us/pubs/42567. |
Development and applications of the LANDFIRE forest structure layers | Toney, C., Peterson, B., Long, D., Parsons, R., Cohn, G. M. | 2012 | Toney, C., Peterson, B., Long, D., Parsons, R., and Cohn, G.M., 2012, Development and applications of the LANDFIRE forest structure layers, in Moving from Status to Trends—Forest Inventory and Analysis (FIA) Symposium 2012, Baltimore, Md., 4-6 December 2012, Gen. Tech. Rep. NRS-P-105: U.S. Forest Service, Northern Research Station, p. 305–309, at https://www.fs.usda.gov/research/treesearch/42767. |
Sensitivity to spatial and temporal scale and fire regime inputs in deriving fire regime condition class | Tedrow, L., Hann, W.J. | 2015 | Tedrow, L., and Hann, W.J., 2015, Sensitivity to spatial and temporal scale and fire regime inputs in deriving fire regime condition class, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 237–246, at https://www.fs.usda.gov/research/treesearch/49449. |
U.S. Geological Survey development of a Landsat-based fire disturbance ECV | Stitt, S., Guthrie, J., Hawbaker, T., Dolhancey, M. | 2011 | Stitt, S., Guthrie, J., Hawbaker, T., and Dolhancey, M., 2011, U.S. Geological Survey development of a Landsat-based fire disturbance ECV, in 34th International Symposium on Remote Sensing of Environment, The GEOSS Era—Towards Operational Environmental Monitoring, Sydney, NSW, Australia, 10–15 April 2011, Proceedings: International Society for Photogrammetry and Remote Sensing, at https://www.isprs.org/proceedings/2011/ISRSE-34/. |
A formal framework for disaster risk properties | Stephen, S., Schildhauer, M., Currier, K., Hitzler, P., Shimizu, C., Janowicz, K., Rehberger, D. | 2023 | Stephen, S., Schildhauer, M., Currier, K., Hitzler, P., Shimizu, C., Janowicz, K., and Rehberger, D., 2023, A formal framework for disaster risk properties, in Ontology Showcase and Demonstrations Track, 9th Joint OntologyWorkshops (JOWO 2023), co-located with FOIS 2023, Sherbrooke, Québec, Canada, 19-20 July 2023, CEUR Workshop Proceedings: Bern, Switzerland, International Association for Ontology and its Applications, paper 45, at https://ceur-ws.org/Vol-3637/paper48.pdf. |
Comparison of six fire severity classification methods using Montana and Washington wildland fires | Sikkink, P.G. | 2015 | Sikkink, P.G., 2015, Comparison of six fire severity classification methods using Montana and Washington wildland fires, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 213–226, at https://www.fs.usda.gov/research/treesearch/49447. |
Use of state-and-transition simulation modeling in national forest planning in the Pacific Northwest, U.S.A. | Shlisky, A. J., Vandendriesche, D. | 2012 | Shlisky, A.J., and Vandendriesche, D., 2012, Use of state-and-transition simulation modeling in national forest planning in the Pacific Northwest, U.S.A., in First Landscape State-and-Transition Simulation Modeling Conference, Portland, Oreg., 14–16 June 2011, Proceedings, General Technical Report PNW-GTR-869: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, p. 23–42, at https://www.fs.usda.gov/research/treesearch/42567. |
Automated burned area identification in real-time during wildfire events using WorldView imagery for the insurance industry | Schulz, Karsten, Michel, Ulrich, Geller, Christina | 2018 | Schulz, K., Michel, U., and Geller, C., 2018, Automated burned area identification in real-time during wildfire events using WorldView imagery for the insurance industry, in Earth Resources and Environmental Remote Sensing/GIS Applications IX, Berlin, Germany, 10-13 September 2018, Proc. of SPIE Vol. 10790: Bellingham, Wash., Society of Photo-Optical Instrumentation Engineers, paper 1079015, at https://doi.org/10.1117/12.2324458. |
Long-term post-wildfire correlates with avian community dynamics in ponderosa pine forests | Sanderlin, J.S., Block, W.M., Strohmeyer, B.E. | 2015 | Sanderlin, J.S., Block, W.M., and Strohmeyer, B.E., 2015, Long-term post-wildfire correlates with avian community dynamics in ponderosa pine forests, in 12th Biennial Conference of Research on the Colorado Plateau, Flagstaff, Ariz., 16–19 September 2013, Proceedings, U.S. Geological Survey Scientific Investigations Report 2015–5180: Reston, Va., U.S. Geological Survey, p. 89–101, at https://doi.org/10.3133/sir20155180. |
Assessing predictive services' 7-day fire potential outlook | Riley, Karin, Stonesifer, Crystal, Calkin, Dave, Preisler, Haiganoush | 2015 | Riley, K., Stonesifer, C., Calkin, D., and Preisler, H., 2015, Assessing predictive services' 7-day fire potential outlook, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 188–195, at https://www.fs.usda.gov/treesearch/pubs/49443. |
Attribute-based K-Means algorithm | Prakash, A., Chungkham, Y. S., Ansari, M. Y. | 2019 | Prakash, A., Chungkham, Y.S., and Ansari, M.Y., 2019, Attribute-based K-Means algorithm, in 2019 International Conference on Computing, Communication, and Intelligent Systems, ICCCIS 2019, Greater Noida, India, 18–19 October 2019, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 41–45, at https://doi.org/10.1109/ICCCIS48478.2019.8974460. |
Wildfires identification—Semantic segmentation using support vector machine classifier | Pecha, Marek, Langford, Zachary, Horák, David, Tran Mills, Richard | 2022 | Pecha, M., Langford, Z., Horák, D., and Tran Mills, R., 2022, Wildfires identification—Semantic segmentation using support vector machine classifier, in Programs and Algorithms of Numerical Mathematics, PANM 21, Janov nad Nisou, Czech Republic, 19–24 June 2022, Proceedings of Seminar: Prague, Czech Republic, Institute of Mathematics CAS, p. 173–186, at https://doi.org/10.21136/panm.2022.16. |
Determination of optimal set of spatio-temporal features for predicting burn probability in the state of California, USA | Pastorino, Javier, Director, Joseph W., Biswas, Ashis Kumer, Hawbaker, Todd J. | 2022 | Pastorino, J., Director, J.W., Biswas, A.K., and Hawbaker, T.J., 2022, Determination of optimal set of spatio-temporal features for predicting burn probability in the state of California, USA, in ACM Southeast Conference, Virtual Event, 19–20 April 2022, Proceedings: New York, N.Y., Association for Computing Machinery, p. 151–158, at https://doi.org/10.1145/3476883.3520228. |
N/A | Oetgen, J., Dube, A., Chamberlain, M.J., Engeling, A., Skow, K.L., Collier, B.A. | 2016 | Oetgen, J., Dube, A., Chamberlain, M.J., Engeling, A., Skow, K.L., and Collier, B.A., 2016, Evaluating Rio Grande wild turkey movements post catastrophic wildfire using 2 selection analysis approaches, in 11th National Wild Turkey Symposium, Tucson, Ariz., 5–7 January 2016, Proceedings: Edgefield, S.C., National Wild Turkey Federation, p. 127–141. |
Rapid response tools and datasets for post-fire erosion modeling—Linking remote sensing and process-based hydrological models to support post-fire remediation | Miller, M. E., Elliot, W. J., Endsley, K. A., Robichaud, P. R., Billmire, M. | 2014 | Miller, M.E., Elliot, W.J., Endsley, K.A., Robichaud, P.R., and Billmire, M., 2014, Rapid response tools and datasets for post-fire erosion modeling—Linking remote sensing and process-based hydrological models to support post-fire remediation, in ISPRS Technical Commission I Symposium, Denver, Colo., 17–20 November 2014, ISPRS Archives XL-1: International Society for Photogrammetry and Remote Sensing, p. 257–263, at https://doi.org/10.5194/isprsarchives-XL-1-257-2014. |
Rapid response tools and datasets for post-fire modeling—Linking Earth observations and process-based hydrological models to support post-fire remediation | Miller, M. E., Billmire, M., Elliot, W. J., Endsley, K. A., Robichaud, P. R. | 2015 | Miller, M.E., Billmire, M., Elliot, W.J., Endsley, K.A., and Robichaud, P.R., 2015, Rapid response tools and datasets for post-fire modeling—Linking Earth observations and process-based hydrological models to support post-fire remediation, in 36th International Symposium on Remote Sensing of Environment, Berlin, Germany, 11–15 May 2015, ISPRS Archives XL-7/W3: International Society for Photogrammetry and Remote Sensing, p. 469–476, at https://doi.org/10.5194/isprsarchives-XL-7-W3-469-2015. |
Burn severity mapping in Australia 2009 | McKinley, R., Clark, J., Lecker, J. | 2012 | McKinley, R., Clark, J., and Lecker, J., 2012, Burn severity mapping in Australia 2009, in XXII ISPRS Congress, Melbourne, Australia, 25 August – 01 September 2012, ISPRS Archives XXXIX-B8: International Society for Photogrammetry and Remote Sensing, p. 51–54, at https://doi.org/10.5194/isprsarchives-XXXIX-B8-51-2012. |
Comparative fire emissions analysis—The DEASCO3 project and the EPA 2008 NEI | Mavko, M. E., Moore, T., Randall, D., Fitch, M. | 2012 | Mavko, M.E., Moore, T., Randall, D., and Fitch, M., 2012, Comparative fire emissions analysis—The DEASCO3 project and the EPA 2008 NEI, in Aerosol and Atmospheric Optics—Visibility and Air Pollution Specialty Conference 2012, Whitefish, Mont., 25–28 September 2012, Proceedings: Pittsburgh, Pa., Air and Waste Management Association, p. 239–246, at https://www3.epa.gov/ttn/chief/conference/ei20/session2/mmavko.pdf. |
Fire effects on evapotranspiration in the Upper Rio Grande Basin using Landsat-based SSEBop | Mankin, K. R., Patel, R. | 2021 | Mankin, K.R., and Patel, R., 2021, Fire effects on evapotranspiration in the Upper Rio Grande Basin using Landsat-based SSEBop, in American Society of Agricultural and Biological Engineers Annual International Meeting, ASABE 2021, Virtual Meeting, 12–16 July 2021, Proceedings, v. 4: St. Joseph, Mich., American Society of Agricultural and Biological Engineers, p. 2428–2437, at https://doi.org/10.13031/aim.202101065. |
Individual tree level forest fire assessment using bi-temporal LiDAR data | Ma, Q., Hu, T., Su, Y., Guo, Q., Battles, J. J., Kelly, M. | 2018 | Ma, Q., Hu, T., Su, Y., Guo, Q., Battles, J.J., and Kelly, M., 2018, Individual tree level forest fire assessment using bi-temporal LiDAR data, in 38th Annual IEEE International Geoscience and Remote Sensing Symposium, IGARSS 2018, Valencia, Spain, 22–27 July 2018, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 4308–4311, at https://doi.org/10.1109/IGARSS.2018.8519445. |
Wildfire mapping in interior Alaska using deep neural networks on imbalanced datasets | Langford, Z., Kumar, J., Hoffman, F. | 2019 | Langford, Z., Kumar, J., and Hoffman, F., 2019, Wildfire mapping in interior Alaska using deep neural networks on imbalanced datasets, in 18th IEEE International Conference on Data Mining Workshops, ICDMW 2018, Singapore, 7–20 November 2018, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 770–778, at https://doi.org/10.1109/ICDMW.2018.00116. |
Approaches to incorporating climate change effects in state and transition simulation models of vegetation | Kerns, B. K., Hemstrom, M. A., Conklin, D., Yospin, G. I., Johnson, B., Bachelet, D., Bridgham, S. | 2012 | Kerns, B.K., Hemstrom, M.A., Conklin, D., Yospin, G.I., Johnson, B., Bachelet, D., and Bridgham, S., 2012, Approaches to incorporating climate change effects in state and transition simulation models of vegetation, in First Landscape State-and-Transition Simulation Modeling Conference, Portland, Oreg., 14–16 June 2011, Proceedings, General Technical Report PNW-GTR-869: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, p. 161–172, at https://www.fs.usda.gov/treesearch/pubs/42576. |
Assessing three fuel classification systems and their maps using Forest Inventory and Analysis (FIA) surface fuel measurements | Keane, R.E., Herynk, J.M., Toney, C., Urbanski, S.P., Lutes, D.C., Ottmar, R.D. | 2015 | Keane, R.E., Herynk, J.M., Toney, C., Urbanski, S.P., Lutes, D.C., and Ottmar, R.D., 2015, Assessing three fuel classification systems and their maps using Forest Inventory and Analysis (FIA) surface fuel measurements, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 128–140, at https://www.fs.usda.gov/research/treesearch/49435. |
Classifying heterogeneous sequential data by cyclic domain adaptation—An application in land cover detection | Jia, X., Nayak, G., Khandelwal, A., Karpatne, A., Kumar, V. | 2019 | Jia, X., Nayak, G., Khandelwal, A., Karpatne, A., and Kumar, V., 2019, Classifying heterogeneous sequential data by cyclic domain adaptation—An application in land cover detection, in 2019 SIAM International Conference on Data Mining, Calgary, Alberta, Canada, 2–4 May 2019, Proceedings: Philadelphia, Pa., Society for Industrial and Applied Mathematics, p. 540–548, at https://doi.org/10.1137/1.9781611975673.61. |
Spatial context-aware networks for mining temporal discriminative period in land cover detection | Jia, X., Li, S., Khandelwal, A., Nayak, G., Karpatne, A., Kumar, V. | 2019 | Jia, X., Li, S., Khandelwal, A., Nayak, G., Karpatne, A., and Kumar, V., 2019, Spatial context-aware networks for mining temporal discriminative period in land cover detection, in 2019 SIAM International Conference on Data Mining, Calgary, Alberta, Canada, 2–4 May 2019, Proceedings: Philadelphia, Pa., Society for Industrial and Applied Mathematics, p. 513–521, at https://doi.org/10.1137/1.9781611975673.58. |
Utilizing multi-sensor fire detections to map fires in the United States | Howard, S. M., Picotte, J. J., Coan, M. J. | 2014 | Howard, S.M., Picotte, J.J., and Coan, M.J., 2014, Utilizing multi-sensor fire detections to map fires in the United States, in ISPRS Technical Commission I Symposium, Denver, Colo., 17–20 November 2014, ISPRS Archives XL-1: International Society for Photogrammetry and Remote Sensing, p. 161–166, at https://doi.org/10.5194/isprsarchives-XL-1-161-2014. |
The integrated landscape assessment project | Hemstrom, M. A., Salwasser, J., Halofsky, J., Kagan, J., Comfort, C. | 2012 | Hemstrom, M.A., Salwasser, J., Halofsky, J., Kagan, J., and Comfort, C., 2012, The integrated landscape assessment project, in First Landscape State-and-Transition Simulation Modeling Conference, Portland, Oreg., 14–16 June 2011, Proceedings, General Technical Report PNW-GTR-869: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, p. 57–72, at https://www.fs.usda.gov/research/treesearch/42569. |
Wildfire influence on snow energy balance from 22 years of MODIS land surface albedo | Gayler, J.M., Skiles, S.M. | 2023 | Gayler, J.M., and Skiles, S.M., 2023, Wildfire influence on snow energy balance from 22 years of MODIS land surface albedo, in International Snow Science Workshop, Bend, Oregon, 8–13 October 2023, Proceedings: International Snow Science Workshop, p. 680–686, at https://arc.lib.montana.edu/snow-science/item/2950. |
Monitoring Trends and Burn Severity (MTBS)—Monitoring wildfire activity for the past quarter century using Landsat data | Finco, M. V., Quayle, B., Zhang, Y., Lecker, J., Megown, K.A., Brewer, C.K. | 2012 | Finco, M.V., Quayle, B., Zhang, Y., Lecker, J., Megown, K.A., and Brewer, C.K., 2012, Monitoring Trends and Burn Severity (MTBS)—Monitoring wildfire activity for the past quarter century using Landsat data, in Moving from Status to Trends—Forest Inventory and Analysis (FIA) Symposium 2012, Baltimore, Md., 4-6 December 2012, Gen. Tech. Rep. NRS-P-105: U.S. Forest Service, Northern Research Station, p. 222–228, at https://www.fs.usda.gov/research/treesearch/42750. |
Wildland fire potential—A tool for assessing wildfire risk and fuels management needs | Dillon, G.K., Menakis, J. P., Fay, F. | 2015 | Dillon, G.K., Menakis, J.P., and Fay, F., 2015, Wildland fire potential—A tool for assessing wildfire risk and fuels management needs, in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 60–76, at https://www.fs.usda.gov/treesearch/pubs/49429. |
Using state-and-transition models to project cheatgrass and juniper invasion in southeastern Oregon sagebrush steppe | Creutzburg, M. K., Halofsky, J. S., Hemstrom, M. A. | 2012 | Creutzburg, M.K., Halofsky, J.S., and Hemstrom, M.A., 2012, Using state-and-transition models to project cheatgrass and juniper invasion in southeastern Oregon sagebrush steppe, in First Landscape State-and-Transition Simulation Modeling Conference, Portland, Oreg., 14–16 June 2011, Proceedings, General Technical Report PNW-GTR-869: U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, p. 73–84, at https://www.fs.usda.gov/research/treesearch/42570. |
A new data mining framework for forest fire mapping | Chen, X. C., Karpatne, A., Chamber, Y., Mithal, V., Lau, M., Steinhaeuser, K., Boriah, S., Steinbach, M., Kumar, V., Potter, C. S., Klooster, S. A., Abraham, T., Stanley, J. D., Castilla-Rubio, J. C. | 2012 | Chen, X.C., Karpatne, A., Chamber, Y., Mithal, V., Lau, M., Steinhaeuser, K., Boriah, S., Steinbach, M., Kumar, V., et al., 2012, A new data mining framework for forest fire mapping, in Conference on Intelligent Data Understanding, CIDU 2012, Boulder, Colo., 24–26 October 2012, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 104–111, at https://doi.org/10.1109/CIDU.2012.6382190. |
Remote sensing techniques to assess post-fire effects at the hillslope and sub-basin scales via multi-scale model | Brook, A., Polinova, M., Kopel, D., Malkinson, D., Wittenberg, L., Roberts, D., Shtober-Zisu, N. | 2017 | Brook, A., Polinova, M., Kopel, D., Malkinson, D., Wittenberg, L., Roberts, D., and Shtober-Zisu, N., 2017, Remote sensing techniques to assess post-fire effects at the hillslope and sub-basin scales via multi-scale model, in ISPRS Hannover Workshop—HRIGI 17 - CMRT 17 - ISA 17 - EuroCOW 17, Hannover, Germany, 6–9 June 2017, ISPRS Archives XLII-1/W1, 2: International Society for Photogrammetry and Remote Sensing, p. 135–141, at https://doi.org/10.5194/isprs-archives-XLII-1-W1-135-2017. |
Multi-scale analysis of jack pine saplings after fire across burn severities | Bomber, M., Portelli, R. | 2020 | Bomber, M., and Portelli, R., 2020, Multi-scale analysis of jack pine saplings after fire across burn severities, in XXIV ISPRS Congress, online, 2020 edition, ISPRS Archives XLIII-B3: International Society for Photogrammetry and Remote Sensing, p. 671–675, at https://doi.org/10.5194/isprs-archives-XLIII-B3-2020-671-2020. |
Contemporary patterns of burn severity heterogeneity from fires in the northwestern U.S. | Belote, R.T. | 2015 | Belote, R.T., 2015, Contemporary patterns of burn severity heterogeneity from fires in the northwestern U.S., in Large Wildland Fires Conference, Missoula, Mont., 19–23 May 2014, USDA Forest Service Proceedings Proc. RMRS-P-73: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, p. 252–256, at https://www.fs.usda.gov/treesearch/pubs/49451. |
Density-based cluster detection at multiple spatial scales via kullback-leibler divergence of reachability profiles | Aydin, O., Osorio-Murillo, C., Huang, C.-C. | 2022 | Aydin, O., Osorio-Murillo, C., and Huang, C.-C., 2022, Density-based cluster detection at multiple spatial scales via kullback-leibler divergence of reachability profiles, in GeoAI '22—Proceedings of the 5th ACM SIGSPATIAL International Workshop on AI for Geographic Knowledge Discovery, Seattle, Wash., 1–4 November 2022, Proceedings: New York, N.Y., Association for Computing Machinery, p. 66–75, at https://doi.org/10.1145/3557918.3565870. |
Assessing wildfire burn severity indices using Sentinel-2 Data—A comparative study of common remote sensing burn indices and CBI field data | Atakul, Canan, Di, Liping | 2023 | Atakul, C., and Di, L., 2023, Assessing wildfire burn severity indices using Sentinel-2 Data—A comparative study of common remote sensing burn indices and CBI field data, in 11th International Conference on Agro-Geoinformatics, Wuhan, China, 25–28 July 2023, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 1–5, at https://doi.org/10.1109/Agro-Geoinformatics59224.2023.10233309. |
Wildfire Emergency Response Hazard Extraction and Analysis of Trends (HEAT) through natural language processing and time series | Andrade, Sequoia R., Walsh, Hannah S. | 2021 | Andrade, S.R., and Walsh, H.S., 2021, Wildfire Emergency Response Hazard Extraction and Analysis of Trends (HEAT) through natural language processing and time series, in 2021 IEEE/AIAA 40th Digital Avionics Systems Conference (DASC), San Antonio, Tex., 3–7 October 2021, Proceedings: Piscataway, N.J., Institute of Electrical and Electronics Engineers, p. 1–10, at https://doi.org/10.1109/dasc52595.2021.9594501. |