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Bright BC. Landsat time series and lidar as predictors of live and dead basal area across five bark beetle-affected forests Hudak AT, ed. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing. 2014;7(8). Available at: http://www.treesearch.fs.fed.us/pubs/49638.
T. McCarley R. Landscape-scale quantification of fire-induced change in canopy cover following mountain pine beetle outbreak and timber harvest Kolden CA, ed. Forest Ecology and Management. 2017;391.
T. McCarley R. Landscape-scale quantification of fire-induced change in canopy cover following mountain pine beetle outbreak and timber harvest Kolden CA, ed. Forest Ecology and Management. 2017;391.
Kolden CA. Limitations and utilisation of Monitoring Trends in Burn Severity products for assessing wildfire severity in the USA Smith AMS, ed. International Journal of Wildland Fire. 2015;Online early.
Syphard AD. Location, timing and extent of wildfire vary by cause of ignition Keeley JE, ed. International Journal of Wildland Fire. 2015;24.
Knapp EE. Long-term dead wood changes in a Sierra Nevada mixed conifer forest: habitat and fire hazard implications. Forest Ecology and Management. 2015;339.
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).
Reis SA. Long-Term Effects of Fire on Vegetation Structure and Predicted Fire Behavior in Wyoming Big Sagebrush Ecosystems Ellsworth LM, ed. Ecosystems. 2018;(Online ISSN 1435-0629).
Jang W. Long-term effects on distribution of forest biomass following different harvesting levels in the northern Rocky Mountains Keyes CR, ed. Forest Ecology and Management. 2015;358.
M
Colavito MM. Making the Transition from Science Delivery to Knowledge Coproduction in Boundary Spanning: A Case Study of the Alaska Fire Science Consortium .F.Trainor S, ed. AMS. 2019;Online.
Kemp KB. Managing for climate change on federal lands of the western United States: perceived usefulness of climate science, effectiveness of adaptation strategies, and barriers to implementation Blades JJ, ed. Ecology and Society. 2015;20(2).
Kemp KB. Managing for climate change on federal lands of the western United States: perceived usefulness of climate science, effectiveness of adaptation strategies, and barriers to implementation Blades JJ, ed. Ecology and Society. 2015;20(2).
Kline JD, Kerns BK, Day MA, Hammer RB. Mapping multiple forest threats in the northwestern United States. Journal of Forestry. 2013;111(3).
Kline JD, Kerns BK, Day MA, Hammer RB. Mapping multiple forest threats in the northwestern United States. Journal of Forestry. 2013;111(3).
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.PDF icon Goldstein and Kennedy_2022_IJWF_Mapping the ethical landscape of wildland fire management.pdf (900.38 KB)
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.
Haugo RD. The missing fire: quantifying human exclusion of wildfire in Pacific Northwest forests, USA Kellogg BS, ed. Ecosphere. 2019;10(4).
French NHF. Modeling Regional-Scale Wildland Fire Emissions with the Wildland Fire Emissions Information System McKenzie D, ed. Earth Interactions. 2014;18.PDF icon ei-d-14-0002%2E1.pdf (1.8 MB)
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.
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.
T. McCarley R. Multi-temporal LiDAR and Landsat quantification of fire-induced changes to forest structure Kolden CA, ed. Remote Sensing of Environment. 2017;191.
T. McCarley R. Multi-temporal LiDAR and Landsat quantification of fire-induced changes to forest structure Kolden CA, ed. Remote Sensing of Environment. 2017;191.
T. McCarley R. Multi-temporal LiDAR and Landsat quantification of fire-induced changes to forest structure Kolden CA, ed. Remote Sensing of Environment. 2017;191.
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Brown MJ, Kertis J, Huff MH. Natural tree regeneration and coarse woody debris dynamics after a forest fire in the Western Cascade range. Portland: USDA Forest Service, Pacific Northwest Research Station; 2013:50. Available at: http://www.treesearch.fs.fed.us/pubs/43434.PDF icon pnw_rp592.pdf (1.58 MB)
Buotte PC. Near-future forest vulnerability to drought and fire varies across the western United States Levis S, ed. Global Change Biology. 2019;25(1).

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