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Found 1096 results

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Goldstein D, Kennedy EB. Mapping the ethical landscape of wildland fire management: setting an agendum for research and deliberation on the applied ethics of wildland fire. International Journal of Wildland Fire. 2022;Online.

Goldstein and Kennedy_2022_IJWF_Mapping the ethical landscape of wildland fire management.pdf (900.38 KB)

Oliver M. Mapping the Future: U.S. Exposure to Multiple Landscape Stressors. Portland: US Department of Agriculture, Forest Service, Pacific Northwest Research Station; 2017.

scifi197.pdf (6.8 MB)

Masticating Fuels: Effects on Prescribed Fire Behavior and Subsequent Vegetation Effects. Joint Fire Science Program; 2009:6. Available at: http://www.firescience.gov/projects/briefs/03-3-2-06_FSBrief47.pdf.

Reiner AL, Vaillant NM, Dailey SN. Mastication and Prescribed Fire Influences on Tree Mortality and Predicted Fire Behavior in Ponderosa Pine. Western Journal of Applied Forestry. 2012;27(1):6. Available at: http://www.ingentaconnect.com/content/saf/wjaf/2012/00000027/00000001/art00006.

Sullivan EA, McDonald AG. Mathematical model and sensor development for measuring energy transfer from wildland fires. International Journal of Wildland Fire. 2014;On-line early.

Bennett M, Fitzgerald S. Mechanical Treatments. Corvallis, OR: Oregon State University; 2008:4. Available at: http://extension.oregonstate.edu/catalog/pdf/ec/ec1575-e.pdf.

Jones GM. Megafires: an emerging threat to old-forest species Gutiérrez RJ, ed. Frontiers in Ecology and the Environment. 2016;14(6).

Anon. The merits of prescribed fire outweigh potential carbon emission effects.; 2013.

AFEs-Prescribed-Fire-Position-Paper-2013.pdf (2.71 MB)

Fontaine JB, Kennedy PL. Meta-analysis of avian and small-mammal response to fire severity and fire surrogate treatments in US fire-prone forests. Ecological Applications. 2012;22:15. Available at: http://oregonstate.edu/dept/eoarcunion/sites/default/files/publications/fontaine_kennedy_2012.pdf.

Wollstein K, O’Connor C, Gear J, Hoagland R. Minimize the bad days: Wildland fire response and suppression success. Rangelands. 2022;8(47).

Wollstein et al_2022_Minimize the bad days_Wildland fire response and suppression success.pdf (1.21 MB)

Haugo RD. The missing fire: quantifying human exclusion of wildfire in Pacific Northwest forests, USA Kellogg BS, ed. Ecosphere. 2019;10(4).

Fillmore SD, McCaffrey SM, Smith AMS. A Mixed Methods Literature Review and Framework for Decision Factors That May Influence the Utilization of Managed Wildfire on Federal Lands, USA. Fire. 2021;4(62).

Fillmore et al_2022_Mixed Methods Lit Review and Framework for Decision Factors Influencing Utilization of Managed Wildfire on Fed Lands USA.pdf (4.77 MB)

Heyerdahl EK, Loehman RA, Falk DA. Mixed-severity fire in lodgepole-dominated forests: Are historical regimes sustainable on Oregon's Pumice Plateau, USA?. Canadian Journal of Forest Research. 2014;On-line early. Available at: http://www.nrcresearchpress.com/doi/abs/10.1139/cjfr-2013-0413.

cjfr-2013-0413.pdf (2.25 MB)

Lesmeister DB. Mixed-severity wildfire and habitat of an old-forest obligate .G.Sovern S, ed. Ecosphere. 2019;e02696.

French NHF. Modeling Regional-Scale Wildland Fire Emissions with the Wildland Fire Emissions Information System McKenzie D, ed. Earth Interactions. 2014;18.

ei-d-14-0002%2E1.pdf (1.8 MB)

Hoffman CM. Modeling spatial and temporal dynamics of wind flow and potential fire behavior following a mountain pine beetle outbreak in a lodgepole pine forest Linn R, ed. Agricultural and Forest Meteorology. 2015;204.

Dunn CJ. Modeling the direct effect of salvage logging on long-term temporal fuel dynamics in dry-mixed conifer forests Bailey JD, ed. Forest Ecology and Management. 2015;341.

McKenzie D. Modeling wildfire regimes in forest landscapes: abstracting a complex reality. In: Perera AH, ed. Simulation modeling of forest landscape disturbances. Simulation modeling of forest landscape disturbances. Switzerland: Springer International Publishing; 2015:73-92. Available at: https://www.treesearch.fs.fed.us/pubs/53095.

Hartter J. Modelling Associations between Public Understanding, Engagement and Forest Conditions in the Inland Northwest, USA Stevens FR, ed. PLOS ONE. 2015;10(2).

Ziesler PS, Rideout DB, Reich R. Modelling conditional burn probability patterns for large wildland fires. International Journal of Wildland Fire. 2013.

Wright CS. Models for predicting fuel consumption in sage-brush-dominated ecosystems. Rangeland ecology and management. 2013;66(3):12.

Underwood E. Models predict longer, deeper U.S. droughts. Science. 2015;13.

Cattau ME, Mahood AL, Balch JK, Wessman CA. Modern Pyromes: Biogeographical Patterns of Fire Characteristics across the Contiguous United States. Fire. 2022;5.

Cattau et al_Modern Pyromes_Biol patterns of fire characteristics across contiguous US.pdf (1.85 MB)

Schiks TJ. Modifying the Canadian Fine Fuel Moisture Code for masticated surface fuels Wotton BM, ed. International Journal of Wildland Fire. 2014;Online early. Available at: http://dx.doi.org/10.1071/WF14041.

Kreye JK, Varner MJ, Knapp EE. Moisture desorption in mechanically masticated fuels: effects of particle fracturing and fuelbed compaction. International Journal of Wildland Fire. 2012;21:10.

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