Publications Library
Counteracting wildfire misinformation. Frontiers in Ecology and the Environment. 2022;20(7):392-390.
Jones et al_2022_Front in Ecol Env_Counteracting wildfire misinformation.pdf (79.58 KB)
Jones et al_2022_Front in Ecol Env_Counteracting wildfire misinformation.pdf (79.58 KB). Expanding wildland-urban interface alters forest structure and landscape context in the northern United States. Environmental Research Letters. 2022;18. Expanding wildland-urban interface alters forest structure and landscape context in the northern United States .pdf (2.47 MB)
Expanding wildland-urban interface alters forest structure and landscape context in the northern United States .pdf (2.47 MB). Exploring relationships between perceived suppression capabilities and resident performance of wildfire mitigations. Journal of Environmental Management. 2022;316. Stasiewicz_Paveglio 2022_Exploring relationships between perceived suppression capabilities and resident performance of wildfire mitigations.pdf (2.32 MB)
Stasiewicz_Paveglio 2022_Exploring relationships between perceived suppression capabilities and resident performance of wildfire mitigations.pdf (2.32 MB) Exposures and behavioural responses to wildfire smoke. Nature Human Behavior. 2022. Burke et al_2022_Nature Human Behavior_Exposures and behavioural responses to wildfire smoke.pdf (8.57 MB)
Burke et al_2022_Nature Human Behavior_Exposures and behavioural responses to wildfire smoke.pdf (8.57 MB). 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). Factors Influencing Risk during Wildfires: Contrasting Divergent Regions in the US. Fire. 2022;5(131). NoonanWright and Seielstad_2022_Fire_Factors influencing risk during wildfire_Contrasting divergent regions in US.pdf (2.29 MB)
NoonanWright and Seielstad_2022_Fire_Factors influencing risk during wildfire_Contrasting divergent regions in US.pdf (2.29 MB). Frequency of disturbance mitigates high-severity fire in the Lake Tahoe Basin, California and Nevada. Ecology and Society. 2022;27(1). Maxwell et al_2022_Ecol Society_Frequency of disturbance mitigates high-severity fire in the Lake Tahoe Basin CA and NV.pdf (2.24 MB)
Maxwell et al_2022_Ecol Society_Frequency of disturbance mitigates high-severity fire in the Lake Tahoe Basin CA and NV.pdf (2.24 MB). Governing ecosystem adaptation: An investigation of adaptive capacity within environmental governance networks. Environmental Science and Policy. 2022;134:46-56. Sehrsweeney and Fischer_2022_Governing EcosystemAdaptation_Investigation of Adaptive Capacity within Enviro gov networks.pdf (6.71 MB)
Sehrsweeney and Fischer_2022_Governing EcosystemAdaptation_Investigation of Adaptive Capacity within Enviro gov networks.pdf (6.71 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). Human Fire Use and Management: A Global Database of Anthropogenic Fire Impacts for Modelling. Fire. 2022;5(4). Millington et al_2022_Human Fire Use and Mgmt- A Global Database of Anthropogenic Fire Impacts for Modelling.pdf (3.75 MB)
Millington et al_2022_Human Fire Use and Mgmt- A Global Database of Anthropogenic Fire Impacts for Modelling.pdf (3.75 MB). Human ignitions on private lands drive USFS cross‑boundary wildfire transmission and community impacts in the western US. Scientific Reports. 2022;12(2624). Downing et al_2022_Human ignitions on private lands drive USFS cross-boundary transmission.pdf (5.32 MB)
Downing et al_2022_Human ignitions on private lands drive USFS cross-boundary transmission.pdf (5.32 MB) Incorporating place-based values into ecological restoration. Ecology and Society. 2022;27(3). Wickham et al_2022_Ecol and Soc_Incorporating place-based values into ecological restoration.pdf (2.01 MB)
Wickham et al_2022_Ecol and Soc_Incorporating place-based values into ecological restoration.pdf (2.01 MB). Increasing co-occurrence of fine particulate matter and ground-level ozone extremes in the western United States. Science Advances. 2022;8. Kalashnikov et al_2022_Fine Particulate Matter.pdf (3.24 MB)
Kalashnikov et al_2022_Fine Particulate Matter.pdf (3.24 MB). Increasing co-occurrence of fine particulate matter and ground-level ozone extremes in the western United States. Science Advances. 2022;8. Kalashnikov et al_2022_Fine Particulate Matter.pdf (3.24 MB)
Kalashnikov et al_2022_Fine Particulate Matter.pdf (3.24 MB). Increasing co-occurrence of fine particulate matter and ground-level ozone extremes in the western United States. Science Advances. 2022;8. Kalashnikov et al_2022_Fine Particulate Matter.pdf (3.24 MB)
Kalashnikov et al_2022_Fine Particulate Matter.pdf (3.24 MB) Indigenous fire management and cross-scale fire-climate relationships in the Southwest United States from 1500 to 1900 CE. Science Advances. 2022;8(49). Available at: https://www.science.org/doi/10.1126/sciadv.abq3221. Roos et al_2022_ScienceAdvances_Indigenous fire mgmt and cross-scale fire-climate relationships in the SW US 1500 to 1900 CE.pdf (1.46 MB)
Roos et al_2022_ScienceAdvances_Indigenous fire mgmt and cross-scale fire-climate relationships in the SW US 1500 to 1900 CE.pdf (1.46 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). Passive or Active Management? Understanding Consequences and Changes After Large Stand-Replacing Wildfires. Science Findings. 2022;(247):1-6. Available at: https://www.fs.fed.us/pnw/sciencef/scifi247.pdf. PNW Research Science Findings_2022_Passive or Active Management.pdf (1.18 MB)
PNW Research Science Findings_2022_Passive or Active Management.pdf (1.18 MB) Potential operational delineations: new horizons for proactive, risk-informed strategic land and fire management. Fire Ecology. 2022;18. Thompson et al_2022_FireEcol_PODs as New horizons for proactive risk-informed strategic land and fire mgmt.pdf (7.5 MB)
Thompson et al_2022_FireEcol_PODs as New horizons for proactive risk-informed strategic land and fire mgmt.pdf (7.5 MB) Potential operational delineations: new horizons for proactive, risk-informed strategic land and fire management. Fire Ecology. 2022;18. Thompson et al_2022_FireEcol_PODs as New horizons for proactive risk-informed strategic land and fire mgmt.pdf (7.5 MB)
Thompson et al_2022_FireEcol_PODs as New horizons for proactive risk-informed strategic land and fire mgmt.pdf (7.5 MB) 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. 2022;17(3). Schmidt et al_2022_Quantitative Wildfire Risk Assessment Using a Modular Approach of Geostat Clustering_Case Study in OR.pdf (8.18 MB)
Schmidt et al_2022_Quantitative Wildfire Risk Assessment Using a Modular Approach of Geostat Clustering_Case Study in OR.pdf (8.18 MB) 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. 2022;17(3). Schmidt et al_2022_Quantitative Wildfire Risk Assessment Using a Modular Approach of Geostat Clustering_Case Study in OR.pdf (8.18 MB)
Schmidt et al_2022_Quantitative Wildfire Risk Assessment Using a Modular Approach of Geostat Clustering_Case Study in OR.pdf (8.18 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) 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) 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)
