Publications Library
. Extreme fire spread events and area burned under recent and future climate in the western USA. Global Ecology and Biogeography . 2022;00:1-11.
Global Ecology and Biogeography - 2022 - Coop - Extreme fire spread events and area burned under recent and future climate.pdf (1.25 MB)
Global Ecology and Biogeography - 2022 - Coop - Extreme fire spread events and area burned under recent and future climate.pdf (1.25 MB). Extreme Winds Alter Influence of Fuels and Topography on Megafire Burn Severity in Seasonal Temperate Rainforests under Record Fuel Aridity. Fire. 2022;5(41). Evers et al_2022_Extreme Winds Alter Influence of fuels and topography on megafire burn severity.pdf (1.41 MB)
Evers et al_2022_Extreme Winds Alter Influence of fuels and topography on megafire burn severity.pdf (1.41 MB). A framework for quantifying forest wildfire hazard and fuel treatment effectiveness from stands to landscapes. Fire Ecology. 2022;18(33). Hood et al_2022_FireEcol_A framework for quantifying forest wildfire hazard and fuel treatment effectiveness from stands to landscapes.pdf (1.84 MB)
Hood et al_2022_FireEcol_A framework for quantifying forest wildfire hazard and fuel treatment effectiveness from stands to landscapes.pdf (1.84 MB) Future climate risks from stress, insects and fire across US forests. Ecology letters. 2022;25:1510–1520. Anderegg et al_2022_Future climate risks from stress, insects, and fire across US forests.pdf (3.12 MB)
Anderegg et al_2022_Future climate risks from stress, insects, and fire across US forests.pdf (3.12 MB) Future climate risks from stress, insects and fire across US forests. Ecology letters. 2022;25:1510–1520. Anderegg et al_2022_Future climate risks from stress, insects, and fire across US forests.pdf (3.12 MB)
Anderegg et al_2022_Future climate risks from stress, insects, and fire across US forests.pdf (3.12 MB) Growing impact of wildfire on western US water supply. PNAS. 2022;119(10). Available at: https://www.pnas.org/doi/full/10.1073/pnas.2114069119. pnas.2114069119.pdf (2.09 MB)
pnas.2114069119.pdf (2.09 MB). Growth of the wildland-urban interface within and around U.S. National Forests and Grasslands, 1990–2010. Landscape and Urban Planning. 2022;218. Mockrin et al_2021_Growth of WUI around national forests and grasslands.pdf (2.44 MB)
Mockrin et al_2021_Growth of WUI around national forests and grasslands.pdf (2.44 MB). Growth of the wildland-urban interface within and around U.S. National Forests and Grasslands, 1990–2010. Landscape and Urban Planning. 2022;218. Mockrin et al_2021_Growth of WUI around national forests and grasslands.pdf (2.44 MB)
Mockrin et al_2021_Growth of WUI around national forests and grasslands.pdf (2.44 MB). Interactions Between Fire Refugia and Climate-Environment Conditions Determine Mesic Subalpine Forest Recovery After Large and Severe Wildfires. Frontiers in Forests and Global Change. 2022;5. Busby and Holz_Frontiers_Interactions between fire refugia and climate-enviro conditions determine recovery.pdf (4.67 MB)
Busby and Holz_Frontiers_Interactions between fire refugia and climate-enviro conditions determine recovery.pdf (4.67 MB). Minimize the bad days: Wildland fire response and suppression success. Rangelands. 2022;8(47). Wollstein et al_2022_Minimize the bad days_Wildland fire response and suppression success.pdf (1.21 MB)
Wollstein et al_2022_Minimize the bad days_Wildland fire response and suppression success.pdf (1.21 MB) Network of low-cost air quality sensors for monitoring indoor, outdoor, and personal PM (2.5) exposure in Seattle during the 2020 wildfire season. Atmospheric Environment. 2022;285. Available at: https://www.sciencedirect.com/science/article/pii/S1352231022003090?dgcid=raven_sd_recommender_email. Network of low-cost air quality sensors for monitoring indoor, outdoor, and personal PM2.5 exposure in Seattle during the 2020 wildfire season.pdf (2.79 MB)
Network of low-cost air quality sensors for monitoring indoor, outdoor, and personal PM2.5 exposure in Seattle during the 2020 wildfire season.pdf (2.79 MB) Network of low-cost air quality sensors for monitoring indoor, outdoor, and personal PM (2.5) exposure in Seattle during the 2020 wildfire season. Atmospheric Environment. 2022;285. Available at: https://www.sciencedirect.com/science/article/pii/S1352231022003090?dgcid=raven_sd_recommender_email. Network of low-cost air quality sensors for monitoring indoor, outdoor, and personal PM2.5 exposure in Seattle during the 2020 wildfire season.pdf (2.79 MB)
Network of low-cost air quality sensors for monitoring indoor, outdoor, and personal PM2.5 exposure in Seattle during the 2020 wildfire season.pdf (2.79 MB). Oregon Wildfire Smoke Communications and Impacts: An Evaluation of the 2020 Wildfire Season. Ecosystem Workforce Program Working Paper. 2022;111. Available at: https://scholarsbank.uoregon.edu/xmlui/bitstream/handle/1794/27179/OHA-smoke-survey-report_Final.pdf?sequence=3&isAllowed=y. OHA-smoke-survey-report_2020 Wildfires_Final.pdf (5.71 MB)
OHA-smoke-survey-report_2020 Wildfires_Final.pdf (5.71 MB) Post-fire landscape evaluations in Eastern Washington, USA: Assessing the work of contemporary wildfires. Forest Ecology and Management. 2022;504(2022). Churchill et al 2022 (assessing the work of contemporary wildfires).pdf (12.39 MB)
Churchill et al 2022 (assessing the work of contemporary wildfires).pdf (12.39 MB) 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. 2022;49. Juang et al_2022_Rapid growth of large forest fires drives exponential response of annual forest-fire area to aridity in western US.pdf (1.25 MB)
Juang et al_2022_Rapid growth of large forest fires drives exponential response of annual forest-fire area to aridity in western US.pdf (1.25 MB) Reimagine fire science for the anthropocene. PNAS Nexus. 2022;1(3). Shuman et al_2022_PNAS_Reimagine fire science for the anthropocene.pdf (2.34 MB)
Shuman et al_2022_PNAS_Reimagine fire science for the anthropocene.pdf (2.34 MB). Restoration and fuel hazard reduction result in equivalent reductions in crown fire behavior in dry conifer forests. Ecological Applications. 2022;e2682. Ecological Applications - 2022 - Ritter - Restoration and fuel hazard reduction result in equivalent reductions in crown.pdf (1.98 MB)
Ecological Applications - 2022 - Ritter - Restoration and fuel hazard reduction result in equivalent reductions in crown.pdf (1.98 MB) The right to burn: barriers and opportunities for Indigenous-led fire stewardship in Canada. FACETS. 2022;7:464–481. Hoffman et al_2022_The right to Burn_Barriers and opps for Indgenous-led fire stewardship in Canada.pdf (1.89 MB)
Hoffman et al_2022_The right to Burn_Barriers and opps for Indgenous-led fire stewardship in Canada.pdf (1.89 MB). The Role of Shaded Fuel Breaks in Support of Washington's 20-year Forest Health Strategic Plan: Eastern Washington. Washington State Department of Natural Resources Forest Resilience Division. 2022. Fuel_Break_Memo_Hersey_etal_2022_final.pdf (2.8 MB)
Fuel_Break_Memo_Hersey_etal_2022_final.pdf (2.8 MB). Sand and fire: applying the sandpile model of self-organised criticality to wildfire mitigation. International Journal of Wildland Fire. 2022;Online. Gang et al_2022_IJWF_Sand and Fire_applying sandpile model of self organised criticality to wildfire mitigation.pdf (3.56 MB)
Gang et al_2022_IJWF_Sand and Fire_applying sandpile model of self organised criticality to wildfire mitigation.pdf (3.56 MB). Severity patterns of the 2021 Dixie Fire exemplify the need to increase low-severity fire treatments in California’s forests. Environmental Research Letters. 2022;17. Taylor_2022_Environ._Res._Lett._17_071002.pdf (6.95 MB)
Taylor_2022_Environ._Res._Lett._17_071002.pdf (6.95 MB) Strategic Partnerships to Leverage Small Wins for Fine Fuels Management. Rangeland Ecology & Management. 2022;85. 1-s2.0-S1550742422000884-main.pdf (1.92 MB)
1-s2.0-S1550742422000884-main.pdf (1.92 MB). Transforming fire governance in British Columbia, Canada: an emerging vision for coexisting with fire. Regional Environmental Change. 2022;22(48). Copes-Gerbitz et al 2022_Transforming fire governance in BC, Canda.pdf (1.9 MB)
Copes-Gerbitz et al 2022_Transforming fire governance in BC, Canda.pdf (1.9 MB) Trends in forest structure restoration need over three decades with increasing wildfire activity in the interior Pacific Northwest US. Forest Ecology and Management. 2022;527. Available at: https://doi.org/10.1016/j.foreco.2022.120607. Trends-in-forest-structure-restoration-need-over-three-dec_2023_Forest-Ecolo.pdf (5.61 MB)
Trends-in-forest-structure-restoration-need-over-three-dec_2023_Forest-Ecolo.pdf (5.61 MB). The US Forest Service Life First safety initiative: exploring unnecessary exposure to risk. International Journal of Wildland Fire. 2022;31(10):927–935. Flores and Haire_2022_IJWF_USFS Life Firest Safety initiative_exploring unnecessary exposure to risk.pdf (774.07 KB)
Flores and Haire_2022_IJWF_USFS Life Firest Safety initiative_exploring unnecessary exposure to risk.pdf (774.07 KB)
