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Zobrist K. Assessing tree health. Pullman: Washington State University; 2011:4. Available at: http://cru.cahe.wsu.edu/CEPublications/FS055E/FS055E.pdf.
Ziesler PS, Rideout DB, Reich R. Modelling conditional burn probability patterns for large wildland fires. International Journal of Wildland Fire. 2013.
Ziegler JPaul. Spatially explicit measurements of forest structure and fire behavior following restoration treatments in dry forests Hoffman C, ed. Forest Ecology and Management. 2017;386.
Zhang J, Busse M, Wang S, Young D, Mattson K. Wildfire loss of forest soil C and N: Do pre-fire treatments make a difference?. Science of The Total Environment. 2022;854.PDF icon Zhang et al_2022_Science Total Env_Wildfire loss of forest soil C and N_Do prefire treatments make a difference.pdf (2.1 MB)
Zhai J, Kuusela O-P. Estimating Price Dynamics in the Aftermath of Forest Disturbances: The Biscuit Fire in Southwest Oregon. Forest Science. 2020;66. Available at: https://doi.org/10.1093/forsci/fxaa004.
Zald HSJ, Spies TA, Huso M, Gatziolis D. Climatic, Landform, Microtopographic, and Overstory Canopy Controls of Tree Invasion in a Subalpine Meadow Landscape, Oregon Cascades, USA. Landscape Ecology. 2012;27(8):16. Available at: http://ir.library.oregonstate.edu/xmlui/bitstream/handle/1957/34256/ZaldHaroldForestryClimaticLandformMicrotopographic.pdf?sequence=1.
Zald HSJ. Severe fire weather and intensive forest management increase fire severity in a multi-ownership landscape Dunn CJ, ed. Ecological Applications. 2018;Online early.
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Young MK. The Effect of Wildland Fire on Aquatic Ecosystems in the Western USA Gresswell RE, ed. Forest Ecology and Management. 2003;178(1-2). Available at: http://www.sciencedirect.com/science/journal/03781127/178/1-2.
Yelenik S, Perakis S, Hibbs D. Regional constraints to biological nitrogen fixation in post-fire forest communities. Ecology. 2013;94(3):11. Available at: http://www.esajournals.org/doi/pdf/10.1890/12-0278.1.PDF icon Ecology pub.pdf (838.41 KB)
Yedinak KM. Embracing Complexity to Advance the Science of Wildland Fire Behavior Strand EK, ed. Fire. 2018;1(2).
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Xiang J, Huang C-H, Shirai J, et al. Field measurements of PM2.5 infiltration factor and portable air cleaner effectiveness during wildfire episodes in US residences. Science of the Total Environment. 2021;773. Available at: https://doi.org/10.1016/j.scitotenv.2021.145642.
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Wynecoop MD. Getting back to fire suméŝ: exploring a multi-disciplinary approach to incorporating traditional knowledge into fuels treatments Morgan P, ed. Fire Ecology. 2019;15.
Wright, Jr. HE. The Ecological Role of Fire in Natural Conifer Forests of Western and Northern North America - Introduction Heinselman ML, ed. Fire Ecology. 2014;10(3).
Wright CS, Balog CS, Kelly JW. Estimating volume, biomass, and potential emissions of hand-piled fuels. Portland, OR: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2009:23. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr805.pdf.
Wright CS. Models for predicting fuel consumption in sage-brush-dominated ecosystems. Rangeland ecology and management. 2013;66(3):12.
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)
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.
Woolley T. Beyond red crowns: complex changes in surface and crown fuels and their interactions 32 years following mountain pine beetle epidemics in south-central Oregon, USA Shaw DC, ed. Fire Ecology. 2019;15(4).
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)
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)
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.
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)
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.
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.
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.

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