Publications Library

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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)
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.
Bennett M, Fitzgerald S. Disposing of Woody Material. Corvallis, OR: Oregon State University; 2008:5. Available at: http://extension.oregonstate.edu/catalog/pdf/ec/ec1574-e.pdf.
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)
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.
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.
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)
Fornwalt PJ. Did the 2002 Hayman Fire, Colorado, USA, Burn with Uncharacteristic Severity? Huckaby LS, ed. Fire Ecology. 2016;12(3).
Iverson LR, Matthews SN, Prasad AM, Peters MP, Yohe G. Development of Risk Matrices for Evaluating Climatic Change Responses of Forested Habitats. Climatic Change. 2012;114(2):13. Available at: http://www.nrs.fs.fed.us/pubs/jrnl/2012/nrs_2012_iverson_001.pdf.
Thompson MP. Development and application of a probabilistic method for wildfire suppression cost modeling Haas JR, ed. Forest Policy and Economics. 2015;50.
Moseley C, Davis EJ. Developing Socioeconomic Performance Measures for the Watershed Condition Framework. Eugene, OR: Ecosystem Workforce Program, Institute for a Sustainable Environment, University of Oregon; 2012:24. Available at: http://ewp.uoregon.edu/sites/ewp.uoregon.edu/files/WP_36.pdf.
Halofsky JE. Developing and Implementing Climate Change Adaptation Options in Forest Ecosystems: A Case Study in Southwestern Oregon, USA Peterson DL, ed. Forests. 2016;7(11).
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.
Johnson MC. Developing a post-processor to link the Forest Vegetation Simulator (FVS) and the Fuel Characteristic Classification System (FCCS).; 2015:9 p.PDF icon JFSP 12-1-02-35_final_report.pdf (448.9 KB)
Wei Y. Designing Operationally Relevant Daily Large Fire Containment Strategies Using Risk Assessment Results Thompson MP, ed. Forests. 2019;10(4).
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)
Lane JE, Kruuk LEB, Charmantier A, Murie JO, Dobson SF. Delayed Phenology and Reduced Fitness Associated with Climate Change in a Wild Hibernator. Nature. 2012;489:4. Available at: http://www.nature.com/nature/journal/v489/n7417/full/nature11335.html.
Lannom KO, Tinkham WT, Smith AMS, et al. Defining extreme wildland fires using geospatial and ancillary metrics. International Journal of Wildland Fire. 2014;On-line early.
Tedim F, al. et. Defining extreme wildfire events: Difficulties, challenges, and impacts Leone V, ed. Fire. 2018;1(1).
Holden ZA. Decreasing fire season precipitation increased recent western US forest wildfire activity Swanson A, ed. PNAS. 2018;115(36).
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)
Scheele BC, Driscoll DA, Fischer J, Hunter DA. Decline of an Endangered Amphibian During an Extreme Climatic Event. Ecosphere. 2012;3(art101). Available at: http://www.esajournals.org/doi/pdf/10.1890/ES12-00108.1.
Wilkin KM. Decade-Long Plant Community Responses to Shrubland Fuel Hazard Reduction Ponisio LC, ed. Fire Ecology. 2017;13(2).
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Andrews PL. Current status and future needs of the BehavePlus fire modeling system. International Journal of Wildland Fire. 2013;On-line early.
Reilly MJ. Cumulative effects of wildfires on forest dynamics in the eastern Cascade Mountains, USA Elia M, ed. Ecological Applications. 2018;28(2).

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