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Found 206 results

Filters: First Letter Of Last Name is D [Clear All Filters]

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A

DellaSala DA. Accommodating mixed-severity fire to restore and maintain ecosystem integrity with a focus on the Sierra Nevada of California, USA Hutto RL, ed. Fire Ecology. 2017;13(2).

Schoennagel T. Adapt to more wildfire in western North American forests as climate changes Balch JK, ed. Proceedings of the National Academy of Sciences. 2017;Online early.

Prichard SJ, Hessburg PF, R. Hagmann K, et al. Adapting western North American forests to climate change and wildfires: ten common questions. Ecological Applications. 2021.

Taylor CM, de Jeu RAM, Guichard F, Harris PP, Dorigo WA. Afternoon Rain More Likely Over Drier Soils. Nature. 2012;489:4. Available at: http://www.nature.com/nature/journal/v489/n7416/full/nature11377.html.

Houtman R, Montgomery C, Gagnon A, et al. Allowing a wildfire to burn: estimating the effect on future suppression costs. International Journal of Wildland Fire. 2013;On line early.

Odion DC. Areas of Agreement and Disagreement Regarding Ponderosa Pine and Mixed Conifer Forest Fire Regimes: A Dialogue with Stevens et al. Hanson CT, ed. PLOS One. 2016;11(5).

Ager AA. Assessing the impacts of federal forest planning on wildfire risk-mitigation in the Pacific Northwest, USA Day MA, ed. Landscape and Urban Planning. 2016;147.

Gregg RM. Available Science Assessment Project: Prescribed Fire and Climate Change in Northwest National Forests. (Behan J, ed.).; 2016:151.

ASAP_final_report_1 November.pdf (2 MB)

Stevens JT. Average Stand Age from Forest Inventory Plots Does Not Describe Historical Fire Regimes in Ponderosa Pine and Mixed-Conifer Forests of Western North America Safford HD, ed. PLOS One. 2016;11(5).

Stevens JT. Average Stand Age from Forest Inventory Plots Does Not Describe Historical Fire Regimes in Ponderosa Pine and Mixed-Conifer Forests of Western North America Safford HD, ed. PLOS One. 2016;11(5).

B

Doane D, O'Laughlin J, Morgan P, Miller C. Barriers to wildland fire use: a preliminary problem analysis. 2006.

rmrs_2006_miller_c001.pdf (45.97 KB)

Collins BM. Beyond reducing fire hazard: fuel treatment impacts on overstory tree survival Das AJ, ed. Ecological Applications. 2014;24(8). Available at: http://dx.doi.org/10.1890/14-0971.1 .

Dillon GK. Both topography and climate affected forest and woodland burn severity in two regions of the western US, 1984 to 2006 Holden ZA, ed. Ecosphere. 2011;2(12). Available at: https://www.fs.fed.us/rmrs/publications/both-topography-and-climate-affected-forest-and-woodland-burn-severity-two-regions.

Donato DC. Burning the legacy? Influence of wildfire reburn on dead wood dynamics in a temperate conifer forest Fontaine JB, ed. Ecosphere. 2016;7(5).

C

Reilly MJ, Zuspan A, Halofsky JS, et al. Cascadia Burning: The historic, but not historically unprecedented, 2020 wildfires in the Pacific Northwest, USA. Ecosphere. 2022;13.

Reilly et al_2022_Cascadia Burning_Historic but not historically unprecedented 2022 wildfires in PNW.pdf (9.62 MB)

Reilly MJ, Zuspan A, Halofsky JS, et al. Cascadia Burning: The historic, but not historically unprecedented, 2020 wildfires in the Pacific Northwest, USA. Ecosphere. 2022;13.

Reilly et al_2022_Cascadia Burning_Historic but not historically unprecedented 2022 wildfires in PNW.pdf (9.62 MB)

Reilly MJ, Zuspan A, Halofsky JS, et al. Cascadia Burning: The historic, but not historically unprecedented, 2020 wildfires in the Pacific Northwest, USA. Ecosphere. 2022;13.

Reilly et al_2022_Cascadia Burning_Historic but not historically unprecedented 2022 wildfires in PNW.pdf (9.62 MB)

Reilly MJ, Zuspan A, Halofsky JS, et al. Cascadia Burning: The historic, but not historically unprecedented, 2020 wildfires in the Pacific Northwest, USA. Ecosphere. 2022;13.

Reilly et al_2022_Cascadia Burning_Historic but not historically unprecedented 2022 wildfires in PNW.pdf (9.62 MB)

Dickinson K. Catching Fire? Social Interactions, Beliefs, and Wildfire Risk Mitigation Behaviors Brenkert-Smith H, ed. Society & Natural Resources. 2015;28(8).

Paveglio TB. Categorizing the social context of the wildland urban interface: Adaptive capacity for wildfire and community "archetypes" Moseley C, ed. Forest Science. 2015;61(2).

Morgan P. Challenges of assessing fire and burn severity using field measures, remote sensing and modelling Keane RE, ed. International Journal of Wildland Fire. 2014;23. Available at: http://dx.doi.org/10.1071/WF13058.

Katuwal H. Characterising resource use and potential inefficiencies during large-fire suppression in the western US Dunn CJ, ed. International Journal of Wildland Fire. 2017;26(7).

Falke JA. Climate change and vulnerability of bull trout (Salvelinus confluentus) in a fire-prone landscape Flitcroft RL, ed. Canadian Journal of Fisheries and Aquatic Sciences. 2015;72.

Luce C, Morgan P, Dwire K, et al. Climate Change, Forests, Fire, Water, and Fish: Building Resilient Landscapes, Streams, and Managers. Fort Collins, CO: US Department of Agriculture, Forest Service, Rocky Mountain Research Station; 2012:207. Available at: http://www.fs.fed.us/rm/pubs/rmrs_gtr290.pdf.

Luce C, Morgan P, Dwire K, et al. Climate Change, Forests, Fire, Water, and Fish: Building Resilient Landscapes, Streams, and Managers.; 2012:207. Available at: http://www.firescience.gov/projects/08-2-1-15/project/08-2-1-15_rmrs_gtr290.pdf.

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