Publications Library

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2023
Jose E, Agarwal P, Zhuang J. A data‐driven analysis and optimization of the impact of prescribed fire programs on wildfire risk in different regions of the USA. Natural Hazards. 2023.PDF icon A data-driven analysis and optimization of the impact of prescribed fire programs on wildfire risk in different regions of the USA.pdf (2.13 MB)
Bowman DMJS. Detecting, Monitoring and Foreseeing Wildland Fire Requires Similar Multiscale Viewpoints as Meteorology and Climatology. Fire. 2023.PDF icon Detecting, Monitoring and Foreseeing Wildland Fire Requires Similar Multiscale Viewpoints as Meteorology and Climatology.pdf (1 MB)
Miller CW, Harvey BJ, Kane VR, L. Moskal M, Alvarado E. 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 . 2023. Available at: https://www.publish.csiro.au/wf/pdf/WF22050.PDF icon Different approaches make comparing studies of burn severity challenging- a review of methods used to link remotely sensed data with the Composite Burn Index.pdf (2.49 MB)
Donato DC, Halofsky JS, Churchill DJ, et al. 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. 2023;546.
Abatzoglou JT, Kolden CA, Williams AP, et al. Downslope Wind-Driven Fires in the Western United States. Earth's Future. 2023;11(5).PDF icon Downslope Wind-Driven Fires in the Western United States.pdf (8.46 MB)
Chwalek P, Chen H, Dutta P, et al. Downwind Fire and Smoke Detection during a Controlled Burn—Analyzing the Feasibility and Robustness of Several Downwind Wildfire Sensing Modalities through Real World Applications. Fire. 2023;6(9). Available at: https://www.mdpi.com/2571-6255/6/9/356.PDF icon fire-06-00356.pdf (5.95 MB)
MacDonald G, Wall T, Enquist CAF, et al. Drivers of California’s changing wildfires: a state-of-the-knowledge synthesis. International Journal of Wildland Fire. 2023.PDF icon Drivers of California’s changing wildfires- a state-of-the-knowledge synthesis.pdf (3.08 MB)
Rao K, Williams PA, Diffenbaugh NS, et al. Dry Live Fuels Increase the Likelihood of Lightning-Caused Fires. Geophysical Research Letters. 2023;50.PDF icon Geophysical Research Letters - 2023 - Rao.pdf (1.08 MB)
McDanold JS, Linn RR, Jonko AK, et al. DUET - Distribution of Understory using Elliptical Transport: A mechanistic model of leaf litter and herbaceous spatial distribution based on tree canopy structure. Ecological Modelling. 2023;483.
2022
Belavenutti P, Ager AA, Day MA, Chung W. Designing forest restoration projects to optimize the application of broadcast burning. Ecological Economics. 2022.PDF icon Belavenutti et al_2022_Ecological Econ_Designing forest restoration projects to optimize the application of broadcast burning.pdf (3.12 MB)
2021
Barrett TM, Robertsons GC. Disturbance and Sustainability in Forests of the Western United States. Gen. Tech. Rep. 2021;PNW-GTR-992. Available at: https://www.fs.fed.us/pnw/pubs/pnw_gtr992.pdf?mc_cid=ed4d4f5179&mc_eid=27c88cb9fe.
Schultz CA, Abrams JB, Davis EJ, et al. Disturbance shapes the US forest governance frontier: A review and conceptual framework for understanding governance change. Ambio. 2021;50:2168–2182.PDF icon Schultz et al_2021_Disturbance Shapes US Govt Frontier.pdf (987.73 KB)
2020
Downing WM, Johnston JD, Krawchuk MA, Merschel AG, Rausch JH. Disjunct and decoupled? The persistence of a fire-sensitive conifer soecies in a historically frequent-fire landscape. Journal for Nature Conservation. 2020;55.PDF icon Downing article.pdf (6.76 MB)
Krawchuk MA, Meigs GW, Cartwright JM, et al. Disturbance refugia within mosaics of forest fire, drought, and insect outbreaks. Frontiers in Ecology and the Environment. 2020;18(5).PDF icon pnw_2020_krawchuk001.pdf (4.38 MB)
2019
Wei Y. Designing Operationally Relevant Daily Large Fire Containment Strategies Using Risk Assessment Results Thompson MP, ed. Forests. 2019;10(4).
2018
Holden ZA. Decreasing fire season precipitation increased recent western US forest wildfire activity Swanson A, ed. PNAS. 2018;115(36).
Tedim F, al. et. Defining extreme wildfire events: Difficulties, challenges, and impacts Leone V, ed. Fire. 2018;1(1).
Vaidyanathan A. Developing an online tool for identifying at-risk populations to wildfire smoke hazards Yip F, ed. Science of The Total Environment. 2018;619-620.
Serra-Diaz JM. Disequilibrium of fire-prone forests sets the stage for a rapid decline in conifer dominance during the 21st century Maxwell C, ed. Scientific Reports. 2018;8.
Stephens SL. Drought, Tree Mortality, and Wildfire in Forests Adapted to Frequent Fire Collins BM, ed. BioScience. 2018;68(2).
2017
Wilkin KM. Decade-Long Plant Community Responses to Shrubland Fuel Hazard Reduction Ponisio LC, ed. Fire Ecology. 2017;13(2).
Wright CS. Decomposition Rates for Hand-Piled Fuels. (Evans AM, ed.). Portland: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2017:18p.PDF icon pnw_rn574.pdf (2.75 MB)
Kitzberger T. Direct and indirect climate controls predict heterogeneous early-mid 21st century wildfire burned area across western and boreal North America Falk DA, ed. PLOS One. 2017.
Charnley S. Diversity in forest management to reduce wildfire losses: implications for resilience Spies TA, ed. Ecology and Society. 2017;22(1).
Smith JE. Does the presence of large down wood at the time of a forest fire impact soil recovery? Kluber LA, ed. Forest Ecology and Management. 2017;391.

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