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Noonan-Wright EK. The Effectiveness and Limitations of Fuel Modeling Using the Fire and Fuels Extension to the Forest Vegetation Simulator Vaillant NM, ed. Forest Science. 2014;60(2).PDF icon Noonan-WrightEt_2014_ForSci_CustomFuelModel.pdf (435.82 KB)
Norberg J, Urban MC, Vellend M, Klausmeier CA, Loeuille N. Eco-Evolutionary Responses of Biodiversity to Climate Change. Nature Climate Change. 2012;2(10):5. Available at: http://www.nature.com/nclimate/journal/v2/n10/full/nclimate1588.html.
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O'Connor CD. An empirical machine learning method for predicting potential fire control locations for pre-fire planning and operational fire management Calkin DE, ed. International Journal of Wildland Fire. 2017;26(7).
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Palsa E, Bauer M, Evers C, Hamilton M, Nielsen-Pincus M. Engagement in local and collaborative wildfire risk mitigation planning across the western U.S.—Evaluating participation and diversity in Community Wildfire Protection Plans. Plos One. 2022;17(2).PDF icon Palsa et al 2022_Engagement_in_local_collaborative_wf_risk.pdf (1.3 MB)
Paveglio TB. Exploring the influence of local social context on strategies for achieving Fire Adapted Communities Edgeley C, ed. Fire. 2019;2(2).
Pierson FB. Ecohydrologic impacts of rangeland fire on runoff and erosion: A literature synthesis. (Williams JC, ed.). Fort Collins: US Department of Agriculture, Forest Service, Rocky Mountain Research Station; 2016:110 p. Available at: http://www.fs.fed.us/rm/pubs/rmrs_gtr351.pdf.
Povak NA. Evidence for scale‐dependent topographic controls on wildfire spread Hessburg PF, ed. Ecosphere. 2018;9(10).
Price O. An empirical wildfire risk analysis: the probability of a fire spreading to the urban interface in Sydney, Australia Borah R, ed. International Journal of Wildland Fire. 2015;Online early.
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Raposo JR. Experimental analysis of fire spread across a two-dimensional ridge under wind conditions Cabiddu S, ed. International Journal of Wildland Fire. 2015;Online early.
of Resources WSDN. Eastern Washington Forest Health: Hazards, Accomplishments and Restoration Strategy.; 2014.PDF icon stelprd3822404.pdf (2.47 MB)
Reynolds KM, Hessburg PF, Miller RE, Meurisse RT. Evaluating Soil Risks Associated With Severe Wildfire and Ground-Based Logging. Portland, OR: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2011:27. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr840.pdf.
Rixen C, Dawes MA, Wipf S, Hagedorn F. Evidence of Enhanced Freezing Damage in Treeline Plants During Six Years of CO 2 Enrichment and Soil Warming. Oikos. 2012;121:12. Available at: http://onlinelibrary.wiley.com/doi/10.1111/j.1600-0706.2011.20031.x/abstract?deniedAccessCustomisedMessage=&userIsAuthenticated=false.
Rollins K. The economic benefit of localised, short-term, wildfire-potential information Christman L, ed. International Journal of Wildland Fire. 2015;Online early.
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Scott JH. Examining alternative fuel management strategies and the relative contribution of National Forest System land to wildfire risk to adjacent homes – A pilot assessment on the Sierra National Forest, California, USA Thompson MP, ed. Forest Ecology and Management. 2016;362.
Shaw DS, Lee CA. Expansion of the invasive European mistetoe in California, USA. Botany . 2020;On-line early.
Spencer AG. Enhancing adaptive capacity for restoring fire-dependent ecosystems: the Fire Learning Network’s Prescribed Fire Training Exchanges Schultz CA, ed. Ecology and Society. 2015;20(3).
Spies TA. Examining fire-prone forest landscapes as coupled human and natural systems White EM, ed. Ecology and Society. 2014;19(3).PDF icon ES-2014-6584.pdf (2.12 MB)
Staley DM. Estimating post-fire debris-flow hazards prior to wildfire using a statistical analysis of historical distributions of fire severity from remote sensing data Tillery AC, ed. International Journal of Wildland Fire. 2018;27(9).
Stasiewicz AM, Paveglio TB. Exploring relationships between perceived suppression capabilities and resident performance of wildfire mitigations. Journal of Environmental Management. 2022;316.PDF icon Stasiewicz_Paveglio 2022_Exploring relationships between perceived suppression capabilities and resident performance of wildfire mitigations.pdf (2.32 MB)
Stephens SL, Boerner REJ, Fettig CJ, et al. The Effects of Forest Fuel-Reduction Treatments in the United States. BioScience. 2012;62(6):12. Available at: http://www.fs.fed.us/psw/publications/fettig/psw_2012_fettig001%28stephens%29.pdf.
Stevens-Rumann CS. Evidence for declining forest resilience to wildfires under climate change Kemp KB, ed. Ecology Letters. 2018;21(2).
Stine P. The Ecology and Management of Moist Mixed-Conifer Forests in Eastern Oregon and Washington: a Synthesis of the Relevant Biophysical Science and Implications for Future Land Management. PNW-GTR-897th ed. (Hessburg P, ed.). Pacific Northwest Research Station; 2014. Available at: http://www.fs.fed.us/pnw/pubs/pnw_gtr897.pdf.PDF icon pnw_gtr897.pdf (8.07 MB)
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Tortorelli CM, Krawchuk MA, Kerns BK. Expanding the invasion footprint: Ventenata dubia and relationships to wildfire, environment, and plant communities in the Blue Mountains of the Inland Northwest, USA. Applied Vegetation Science. 2020.PDF icon Tortorelli et al. 2020.pdf (1.78 MB)
Turner DP. Effects of harvest, fire, and pest/pathogen disturbances on the West Cascades ecoregion carbon balance Ritts WD, ed. Carbon Balance and Management. 2015;10(12).
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Urza AK, Weisberg PJ, Board D, et al. Episodic occurrence of favourable weather constrains recovery of a cold desert shrubland after fire. Journal of Applied Ecology. 2021.PDF icon rmrs_2021_urza_a001.pdf (1.39 MB)

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