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Westlind DJ. Long-Term Effects of Burn Season and Frequency on Ponderosa Pine Forest Fuels and Seedlings Kerns BK, ed. Fire Ecology. 2017;13(3).
Westlind DJ, Kerns BK. Repeated fall prescribed fire in previously thinned Pinus ponderosa increases growth and resistance to other disturbances. Forest Ecology and Management. 2021;480.PDF icon pnw_2021_westlind001.pdf (4.39 MB)
Westlind DJ, Kerns BK. Repeated fall prescribed fire in previously thinned Pinus ponderosa increases growth and resistance to other disturbances. Forest Ecology and Management. 2021;480. Available at: https://doi.org/10.1016/j.foreco.2020.118645.
White EM. Use of Science and Modeling by Practitioners in Landscape-Scale Management Decisions Lindberg K, ed. Journal of Forestry. 2019;117(3).
White EM. Social and economic monitoring for the Lakeview Stewardship Collaborative Forest Landscape Restoration Project. (Davis EJ, ed.).; 2015. Available at: http://ewp.uoregon.edu/sites/ewp.uoregon.edu/files/WP_55.pdf.
Whitman E. The climate space of fire regimes in north-western North America Batllori E, ed. Journal of Biogeography. 2015;Online early.
Whittier TR. Tree mortality based fire severity classification for forest inventories: a Pacific Northwest national forests example Gray AN, ed. Forest Ecology and Management. 2016;359.
Wickham SB, Augustine S, Forney A, et al. Incorporating place-based values into ecological restoration. Ecology and Society. 2022;27(3).PDF icon Wickham et al_2022_Ecol and Soc_Incorporating place-based values into ecological restoration.pdf (2.01 MB)
Wiechmann ML. The carbon balance of reducing wildfire risk and restoring process: an analysis of 10-year post-treatment carbon dynamics in a mixed-conifer forest Hurteau MD, ed. Climatic Change. 2015;132(4). Available at: http://link.springer.com/article/10.1007%2Fs10584-015-1450-y.
Wigtil G. Places where wildfire potential and social vulnerability coincide in the coterminous United States Hammer RB, ed. International Journal of Wildland Fire. 2016;Online early.
Wilkin KM. Decade-Long Plant Community Responses to Shrubland Fuel Hazard Reduction Ponisio LC, ed. Fire Ecology. 2017;13(2).
Williams PA. Correlations between components of the water balance and burned area reveal insights for predicting forest fire area in the southwest United States Seager R, ed. International Journal of Wildland Fire. 2014;Online early. Available at: http://dx.doi.org/10.1071/WF14023.
Williams MA, Baker WL. Spatially extensive reconstructions show variable-severity fire and heterogeneous structure in historical western United States dry forests. Global Ecology & Biogeography. 2012;21:11. Available at: http://onlinelibrary.wiley.com/doi/10.1111/j.1466-8238.2011.00750.x/abstract.
Williams PA, Livneh B, McKinnon KA, et al. 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.PDF icon pnas.2114069119.pdf (2.09 MB)
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.
Willms J. The effects of thinning and burning on understory vegetation in North America: A meta-analysis Bartuszevige A, ed. Forest Ecology and Management. 2017;392.
Wilmot TY, Mallia DV, Hallar AG, Lin JC. Wildfire plumes in the Western US are reaching greater heights and injecting more aerosols aloft as wildfire activity intensifies. Scientific Reports. 2022;12(12400).PDF icon Wilmot et al_2022_Wildfire Plumes in western US are reaching greater heights.pdf (1.76 MB)
Wilson PL, Funck JW, Avery RB. Fuelwood Characteristics of Northwestern Conifers and Hardwoods (Updated). Portland, OR: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2010:50. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr810.pdf.
Wilson RS, Ascher TJ, Toman E. The Importance of Framing for Communicating Risk and Managing Forest Health. Journal of Forestry. 2012;110(6):5. Available at: http://dx.doi.org/10.5849/jof.11-058.
Wimberly MC, Cochrane MA, Baer AD, Pabst K. Assessing fuel treatment effectiveness using satellite imagery and spatial statistics. Ecological Applications. 2009;19(6):8. Available at: http://www.esajournals.org/doi/pdf/10.1890/08-1685.1.
Winford EM, Gaither JC. Carbon Outcomes from Fuels Treatment and Bioenergy Production in a Sierra Nevada Forest. Forest Ecology and Management. 2012;282:9. Available at: http://www.sciencedirect.com/science/article/pii/S0378112712003544.
Wirth TA, Pyke DA. Effectiveness of post-fire seeding at the Fitzner-Eberhardt Arid Land Ecology Reserve, Washington. U.S. Geological Survey; 2011:42. Available at: http://pubs.usgs.gov/of/2011/1241/.PDF icon ofr20111241.pdf (1.28 MB)
Wolf R. Not All Fires are Wild - Understanding Fire and Its Use as a Management Tool. (Berger C, ed.).; 2015. Available at: https://catalog.extension.oregonstate.edu/sites/catalog.extension.oregonstate.edu/files/project/pdf/em9114_1.pdf.
Wollstein K, O’Connor C, Gear J, Hoagland R. Minimize the bad days: Wildland fire response and suppression success. Rangelands. 2022;8(47).PDF icon Wollstein et al_2022_Minimize the bad days_Wildland fire response and suppression success.pdf (1.21 MB)
Wood J, Varner M. Burn Back Better How Western States Can Encourage Prescribed Fire on Private Lands. PROPERTY AND ENVIRONMENT RESEARCH CENTER & TALL TIMBERS. 2023. Available at: https://perc.org/2023/01/10/burn-back-better/.PDF icon 2023_PERC-BBB-Report-230104-web.pdf (5.77 MB)

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