Publications Library

Found 1096 results
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Jennings TN, Smith JE, Cromack K, et al. Impact of postfire logging on soil bacterial and fungal communities on biogeochemistry in a mixed-conifer forest in central Oregon. Plant Soil. 2010;350:19. Available at: http://www.fs.fed.us/pnw/pubs/journals/pnw_2012_jennings001.pdf.
Abatzoglou JT. Impact of anthropogenic climate change on wildfire across western US forests Williams PA, ed. Proceedings of the National Academy of Sciences. 2016;113(42).
Kreye JK. The impact of aging on laboratory fire behaviour in masticated shrub fuelbeds of California and Oregon, USA Varner MJ, ed. International Journal of Wildland Fire. 2016;Online early.
R Martin A. Ignition patterns influence fire severity and plant communities in Pacific Northwest, USA, prairies Hamman ST, ed. Fire Ecology. 2016;12(1). Available at: http://fireecologyjournal.org/journal/abstract/?abstract=271.
Fischer PA, Kline JD, Charnley S, Olsen C. Identifying policy target groups with qualitative and quantitative methods: the case of wildfire risk on nonindustrial private forest lands. Forest Policy and Economics. 2013;28.
Churchill DJ. The ICO Approach to Quantifying and Restoring Forest Spatial Pattern: Implementation Guide. Version 3.0. (Jeronimo SMA, ed.). Vashon: Stewardship Forestry and Science, Vashon, Washington, USA.; 2016.PDF icon ICO-Manager-Guide-version-3-1.pdf (6.1 MB)
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Williams JC, Pierson FB, Robichaud PR, Boll J. Hydrologic and erosion responses to wildfire along the rangeland-xeric forest continuum in the western US: a review and model of hydrologic vulnerability. International Journal of Wildland Fire. 2014;On-line early.
Balch JK. Human-started wildfires expand the fire niche across the United States Bradley BA, ed. Proceedings of the National Academy of Sciences. 2017;Online early.
Abatzoglou JT. Human-related ignitions concurrent with high winds promote large wildfires across the USA Balch JK, ed. International Journal of Wildland Fire. 2018;Online early.
Syphard AD. Human presence diminishes the importance of climate in driving fire activity across the United States Keeley JE, ed. PNAS. 2017;114(52).
Downing WM, Dunn CJ, Thompson MP, Caggiano MD, Short KC. Human ignitions on private lands drive USFS cross‑boundary wildfire transmission and community impacts in the western US. Scientific Reports. 2022;12(2624).PDF icon Downing et al_2022_Human ignitions on private lands drive USFS cross-boundary transmission.pdf (5.32 MB)
Millington JDA, Perkins O, Smith C. Human Fire Use and Management: A Global Database of Anthropogenic Fire Impacts for Modelling. Fire. 2022;5(4).PDF icon Millington et al_2022_Human Fire Use and Mgmt- A Global Database of Anthropogenic Fire Impacts for Modelling.pdf (3.75 MB)
Bowman DMJS. Human exposure and sensitivity to globally extreme wildfire events Williamson GJ, ed. Nature Ecology & Evolution. 2017;1.
Coogan SCP, Aftergood O, Flannigan MD. Human- and lightning-caused wildland fire ignition clusters in British Columbia, Canada. International Journal of Wildland Fire. 2022;31(11). Available at: https://doi.org/10.1071/WF21177.PDF icon Coogan et al_2022_IJWF_Human and Lightning caused wildland fire ignition clusters in BC Canada.pdf (10.13 MB)
Parks SA. How will climate change affect wildland fire severity in the western US? Miller C, ed. Environmental Research Letters. 2016;11(3).
Dittrich R, McCallum S. How to measure the economic health cost of wildfires – A systematic review of the literature for northern America. International Journal of Wildland Fire. 2020;29.PDF icon pnw_2020_dittrich001.pdf (290.7 KB)
Heinsch FA. How to generate and interpret fire characteristics charts for the U.S. fire danger rating system. (Andrews PL, ed.). Fort Collins: Department of Agriculture, Forest Service, Rocky Mountain Research Station; 2017:62 p. Available at: https://www.fs.usda.gov/treesearch/pubs/54597.
Calkin DE, Cohen JD, Finney MA, Thompson MP. How risk management can prevent future wildfire disasters in the wildland-urban interface. USDA Forest Service, Rocky Mountain Research Station; 2014. Available at: www.pnas.org/cgi/doi/10.1073/pnas.1315088111.PDF icon PNAS Calkin Final.pdf (686.46 KB)
Dunn CJ. How does tree regeneration respond to mixed‐severity fire in the western Oregon Cascades, USA? Johnston JD, ed. Ecosphere. 2020;11(1).
Collins BM. How does forest recovery following moderate-severity fire influence effects of subsequent wildfire in mixed-conifer forests? Lydersen JM, ed. Fire Ecology. 2018;14(3).
Anon. The hot-dry-windy index: A new tool for forecasting fire weather. Portland: USDA Forest Service PNW Research Station; 2020. Available at: https://www.fs.usda.gov/pnw/ .PDF icon scifi227.pdf (2.74 MB)
Fairbanks R, Ingalsbee T. A Homeowner’s Guide to Fire-Resistant Home Construction. Firefighters United for Safety, Ethics, and Ecology; 2006:8. Available at: http://drupalweb.forestry.oregonstate.edu/forest-owner/sites/default/files/fireresistance.pdf.
Steen-Adams MM. Historical perspective on the influence of wildfire policy, law, and informal institutions on management and forest resilience in a multiownership, frequent-fire, coupled human and natural system in Oregon, USA Charnley S, ed. Ecology and Society. 2017;22(3).
Hagmann RK. Historical patterns of fire severity and forest structure and composition in a landscape structured by frequent large fires: Pumice Plateau ecoregion, Oregon, USA Merschel AG, ed. Landscape Ecology. 2019.
Baker WL. Historical northern spotted owl habitat and old-growth dry forests maintained by mixed-severity wildfires. Landscape Ecology. 2015;30(4).

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