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Davis R. The normal fire environment—Modeling environmental suitability for large forest wildfires using past, present, and future climate normals Yang Z, ed. Forest Ecology and Management. 2017;390.
Davis RJ, Dugger KM, Mohoric S, Evers L, Aney WC. Northwest Forest Plan -- The First 15 Years: Status and Trends of Northern Spotted Owl Populations and Habitats. Portland, OR: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2011:147. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr850.pdf.
Davis RJ, Dugger KM, Mohoric S, Evers L, Aney WC. Northwest Forest Plan -- The First 15 Years: Status and Trends of Northern Spotted Owl Populations and Habitats. Portland, OR: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2011:147. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr850.pdf.
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Duff TJ, Tolhurst KG. Operational wildfire suppression modelling: a review evaluating development, state of the art and future directions. International Journal of Wildland Fire. 2015;24(6).
Coughlan MR, Huber-Stearns H, Clark B, Deak A. 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.PDF icon OHA-smoke-survey-report_2020 Wildfires_Final.pdf (5.71 MB)
Davis EJ. Oregon's State Wood Energy Team: A Grant Program Review.; 2016:16 p.PDF icon WP_69.pdf (2.36 MB)
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Liu JCoco. Particulate air pollution from wildfires in the Western US under climate change Mickley LJ, ed. Climate Change. 2016;138(3).
Wright CS, Vihnanek RE, Restaino JC, Dvorak JE. Photo Series for Quantifying Natural Fuels Volume XI : Eastern Oregon Sagebrush - Steppe and Spotted Owl Nesting Habitat in the Pacific Northwest. Portland, OR: USFS Pacific Northwest Research Station; 2012:85. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr878.pdf?utm_source=Northwest+Fire+Science+Consortium&utm_campaign=a68afc7c28-Weekly_digest_10_1_copy_02_9_28_2012&utm_medium=email.
Diamond SE, Nichols LM, McCoy N, et al. A physiological trait-based approach to predicting the responses of species to experimental climate warming. Ecology. 2012;93:8. Available at: http://www.esajournals.org/doi/pdf/10.1890/11-2296.1.
Diamond SE, Nichols LM, McCoy N, et al. A physiological trait-based approach to predicting the responses of species to experimental climate warming. Ecology. 2012;93:8. Available at: http://www.esajournals.org/doi/pdf/10.1890/11-2296.1.
Ager AA, Evers CR, Day MA, Alcasena FJ, Houtman R. Planning for future fire: Scenario analysis of an accelerated fuel reduction plan for the western United States. Landscape and Urban Planning. 2021;215.PDF icon Ageretal_Planningforfuturefire.pdf (7.01 MB)
Rao K, Williams PA, Diffenbaugh NS, Yebra M, Konings AG. Plant-water sensitivity regulates wildfire vulnerability. Nature Ecology & Evolution. 2022;Online.PDF icon Rao et al_2022_Plant-water_sensitivity_regulates_wildfire_vulnerability.pdf (2.41 MB)
Peterson DW. Post-fire logging produces minimal persistent impacts on understory vegetation in northeastern Oregon, USA Dodson EK, ed. Forest Ecology and Management. 2016;370.
Peterson DW. Post-fire logging reduces surface woody fuels up to four decades following wildfire Dodson EK, ed. Forest Ecology and Management. 2015;338.
Hood SM, Johnson MC, Wagenbrenner JW, Saab VA, Dudley JG. Post-fire Salvage Logging Science Series. 2021. Available at: https://www.nrfirescience.org/hot-topics/post-fire-salvage-logging.
Homann PS. Postwildfire soil trajectory linked to prefire ecosystem structure in Douglas-fir forest Bormann BT, ed. Ecosystems. 2015;18(2).
Dwire KA. Potential effects of climate change on riparian areas, wetlands, and groundwater-dependent ecosystems in the Blue Mountains, Oregon, USA Mellmann-Brown S, ed. Climate Services. 2018;10.
Thompson MP, O’Connor CD, Gannon BM, et al. Potential operational delineations: new horizons for proactive, risk-informed strategic land and fire management. Fire Ecology. 2022;18.PDF icon Thompson et al_2022_FireEcol_PODs as New horizons for proactive risk-informed strategic land and fire mgmt.pdf (7.5 MB)
Kyser GB, Peterson VF, Davy JS, DiTomaso JM. Preemergent Control of Medusahead on California Annual Rangelands with Aminopyralid. Rangeland Ecology and Management. 2012;65(4):8. Available at: http://www.bioone.org/doi/abs/10.2111/REM-D-12-00003.1?af=R.
Kyser GB, Peterson VF, Davy JS, DiTomaso JM. Preemergent Control of Medusahead on California Annual Rangelands with Aminopyralid. Rangeland Ecology and Management. 2012;65(4):8. Available at: http://www.bioone.org/doi/abs/10.2111/REM-D-12-00003.1?af=R.
Hill KC. Prescribed Fire in Grassland Butterfly Habitat: Targeting Weather and Fuel Conditions to Reduce Soil Temperatures and Burn Severity Bakker JD, ed. Fire Ecology. 2017;13(3).
Kerns BK. Prescribed fire regimes subtly alter ponderosa pine forest plant community structure Day MA, ed. Ecosphere. 2018;9(12).
Kerns BK. Prescribed fire regimes subtly alter ponderosa pine forest plant community structure Day MA, ed. Ecosphere. 2019;Open access.
Vogler KC. Prioritization of Forest Restoration Projects: Tradeoffs between Wildfire Protection, Ecological Restoration and Economic Objectives Ager AA, ed. Forests. 2015;6(12).
Ager AA. Production possibility frontiers and socioecological tradeoffs for restoration of fire adapted forests Day MA, ed. Journal of Environmental Management. 2016;176.

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