Articles citing this paper
Analysis of Alaskan burn severity patterns using remotely sensed data
Paul A. Duffy A E , Justin Epting B , Jonathan M. Graham C , T. Scott Rupp A and A. David McGuire D
+ Author Affiliations
- Author Affiliations
A Ecological Dynamics Modeling Group, Department of Forest Sciences, University of Alaska, Fairbanks, AK 99775, USA.
B Center for Applied Biodiversity Science, Conservation International, Washington, DC 20036, USA.
C Department of Mathematical Sciences, University of Montana, Missoula, MT 59812, USA.
D US Geological Survey, Alaska Cooperative Fish and Wildlife Research Unit, University of Alaska, Fairbanks, AK 99775, USA.
E Corresponding author. Email: paul.duffy@uaf.edu
International Journal of Wildland Fire 16(3) 277-284 https://doi.org/10.1071/WF06034
Submitted: 14 March 2006 Accepted: 17 October 2006 Published: 3 July 2007
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Kielland K.,
Euskirchen E.S.,
Brinkman T.J.,
Ruess R.W., Kellie K.A.
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Cahoon Sean M. P.,
Sullivan Patrick F., Gray Andrew N.
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Siberian tundra ecosystem vegetation and carbon stocks four decades after wildfire
Loranty Michael M.,
Natali Susan M.,
Berner Logan T.,
Goetz Scott J.,
Holmes Robert M.,
Davydov Sergei P.,
Zimov Nikita S., Zimov Sergey A.
Journal of Geophysical Research: Biogeosciences. 2014 119(11). p.2144
Seeing the forest beyond the trees
Saatchi Sassan,
Mascaro Joseph,
Xu Liang,
Keller Michael,
Yang Yan,
Duffy Paul,
Espírito‐Santo Fernando,
Baccini Alessandro,
Chambers Jeffery, Schimel David
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Wang Zhuosen,
Erb Angela M.,
Schaaf Crystal B.,
Sun Qingsong,
Liu Yan,
Yang Yun,
Shuai Yanmin,
Casey Kimberly A., Román Miguel O.
Remote Sensing of Environment. 2016 185 p.71
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Cristóbal Jordi,
Graham Patrick,
Buchhorn Marcel, Prakash Anupma
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Kasischke E.S.,
McGuire A.D.,
Turetsky M.R., Kane E.S.
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Bernhardt Emily L.,
Hollingsworth Teresa N., Chapin III F. Stuart
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Quantifying ecological drivers of ecosystem productivity of the early‐successional boreal Larix gmelinii forest
Liu Zhihua, Yang Jian
Ecosphere. 2014 5(7). p.1
Characterizing boreal forest wildfire with multi-temporal Landsat and LIDAR data
Wulder M.A.,
White J.C.,
Alvarez F.,
Han T.,
Rogan J., Hawkes B.
Remote Sensing of Environment. 2009 113(7). p.1540
Plant toxins and trophic cascades alter fire regime and succession on a boreal forest landscape
Feng Zhilan,
Alfaro-Murillo Jorge A.,
DeAngelis Donald L.,
Schmidt Jennifer,
Barga Matthew,
Zheng Yiqiang,
Ahmad Tamrin Muhammad Hanis B.,
Olson Mark,
Glaser Tim,
Kielland Knut,
Chapin F. Stuart, Bryant John
Ecological Modelling. 2012 244 p.79
Variation in plant community composition and vegetation carbon pools a decade following a severe fire season in interior Alaska
Gibson Carolyn M.,
Turetsky Merritt R.,
Cottenie Karl,
Kane Evan S.,
Houle Gregory,
Kasischke Eric S., Gilliam Frank
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Tanase Mihai,
Bennett Lauren, Aponte Cristina
Remote Sensing. 2018 10(11). p.1680
Daily burned area and carbon emissions from boreal fires in Alaska
Veraverbeke S.,
Rogers B. M., Randerson J. T.
Biogeosciences. 2015 12(11). p.3579
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Remote Sensing. 2012 4(2). p.456
Potential shifts in dominant forest cover in interior Alaska driven by variations in fire severity
Barrett K.,
McGuire A. D.,
Hoy E. E., Kasischke E. S.
Ecological Applications. 2011 21(7). p.2380
Using Landsat data to assess fire and burn severity in the North American boreal forest region: an overview and summary of results
French Nancy H. F.,
Kasischke Eric S.,
Hall Ronald J.,
Murphy Karen A.,
Verbyla David L.,
Hoy Elizabeth E., Allen Jennifer L.
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Effects of natural resource development on the terrestrial biodiversity of Canadian boreal forests
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Thompson I.D.,
Fleming R.,
Malcolm J.,
Aubin I.,
Trofymow J.A.,
Langor D.,
Sturrock R.,
Patry C.,
Outerbridge R.O.,
Holmes S.B.,
Haeussler S.,
De Grandpré L.,
Chen H.Y.H.,
Bayne E.,
Arsenault A., Brandt J.P.
Environmental Reviews. 2014 22(4). p.457
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Shamir Ron,
Siqueira Andreia,
White John,
O'Connor Alice,
Butcher Gary,
Garvey Mark, Niven Michael
International Journal of Wildland Fire. 2009 18(8). p.1010
Wildfire Consumption and Interannual Impacts by Land Cover in Alaskan Boreal Forest
Kolden Crystal A., Abatzoglou John T.
Fire Ecology. 2012 8(1). p.98
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Loboda Tatiana,
McGuire A. D.,
Genet Hélène,
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Geomatics, Natural Hazards and Risk. 2011 2(1). p.15
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Geography Compass. 2010 4(2). p.67
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Rupp T. Scott,
Olson Mark A., Duffy Paul A.
Arctic, Antarctic, and Alpine Research. 2012 44(3). p.319
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Pastick Neal J.,
Rigge Matthew,
Wylie Bruce K.,
Jorgenson M. Torre,
Rose Joshua R.,
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Goetz S J,
Mack M C,
Gurney K R,
Randerson J T, Houghton R A
Environmental Research Letters. 2007 2(4). p.045031
Wildfire patterns and landscape changes in Mediterranean oak woodlands
Guiomar N.,
Godinho S.,
Fernandes P.M.,
Machado R.,
Neves N., Fernandes J.P.
Science of The Total Environment. 2015 536 p.338
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Hansen Winslow D.,
Chapin F. Stuart,
Naughton Helen T.,
Rupp T. Scott, Verbyla David
Forest Ecology and Management. 2016 369 p.38
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Earth System Science Data. 2021 13(5). p.1925
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Lewis Sarah A.,
Hudak Andrew T.,
Ottmar Roger D.,
Robichaud Peter R.,
Lentile Leigh B.,
Hood Sharon M.,
Cronan James B., Morgan Penny
International Journal of Wildland Fire. 2011 20(2). p.255
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Applied Geography. 2015 56 p.232
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Yang Jian,
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International Journal of Wildland Fire. 2015 24(3). p.433
Modeling impacts of fire severity on successional trajectories and future fire behavior in Alaskan boreal forests
Johnstone Jill F.,
Rupp T. Scott,
Olson Mark, Verbyla David
Landscape Ecology. 2011 26(4). p.487
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Karau Eva C., Keane Robert E.
International Journal of Wildland Fire. 2010 19(6). p.710
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Kolden Crystal A.,
Lutz James A.,
Key Carl H.,
Kane Jonathan T., van Wagtendonk Jan W.
Forest Ecology and Management. 2012 286 p.38
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Boelman Natalie T.,
Rocha Adrian V., Shaver Gaius R.
International Journal of Remote Sensing. 2011 32(22). p.7033
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Brubaker Linda B.,
Higuera Philip E.,
Rupp T. Scott,
Olson Mark A.,
Anderson Patricia M., Hu Feng Sheng
Ecology. 2009 90(7). p.1788
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Morgan Penelope,
Hudak Andrew T.,
Bobbitt Michael J.,
Lewis Sarah A.,
Smith Alistair M. S., Robichaud Peter R.
Fire Ecology. 2007 3(1). p.91
Persistent effects of fire severity on early successional forests in interior Alaska
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Johnstone Jill F.,
Kasischke Eric S., Kielland Knut
Forest Ecology and Management. 2011 261(3). p.381
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Gustine David D.,
Brinkman Todd J.,
Lindgren Michael A.,
Schmidt Jennifer I.,
Rupp T. Scott,
Adams Layne G., Bond-Lamberty Ben
PLoS ONE. 2014 9(7). p.e100588
Characterization of biophysical contexts leading to severe wildfires in Portugal and their environmental controls
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Martins Samuel, Fernandes Paulo M.
Science of The Total Environment. 2023 875 p.162575
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BECK PIETER S. A.,
GOETZ SCOTT J.,
MACK MICHELLE C.,
ALEXANDER HEATHER D.,
JIN YUFANG,
RANDERSON JAMES T., LORANTY M. M.
Global Change Biology. 2011 17(9). p.2853
Remote Sensing Techniques in Monitoring Post-Fire Effects and Patterns of Forest Recovery in Boreal Forest Regions: A Review
Chu Thuan, Guo Xulin
Remote Sensing. 2013 6(1). p.470
Scale effects of vegetation and topography on burn severity under prevailing fire weather conditions in boreal forest landscapes of Northeastern China
Wu Zhiwei,
He Hong S.,
Bobryk Christopher W., Liang Yu
Scandinavian Journal of Forest Research. 2014 29(1). p.60
Climate, fire size, and biophysical setting control fire severity and spatial pattern in the northern Cascade Range, USA
Cansler C. Alina, McKenzie Donald
Ecological Applications. 2014 24(5). p.1037
Dispersal limitation drives successional pathways in Central Siberian forests under current and intensified fire regimes
Tautenhahn Susanne,
Lichstein Jeremy W.,
Jung Martin,
Kattge Jens,
Bohlman Stephanie A.,
Heilmeier Hermann,
Prokushkin Anatoly,
Kahl Anja, Wirth Christian
Global Change Biology. 2016 22(6). p.2178
The spatial variation in forest burn severity in Heilongjiang Province, China
Chang Yu,
Zhu Zhiliang,
Feng Yuting,
Li Yuehui,
Bu Rencang, Hu Yuanman
Natural Hazards. 2016 81(2). p.981
Insurance Fraud Identification using Computer Vision and IoT: A Study of Field Fires
Sahni Srishti,
Mittal Anmol,
Kidwai Farzil,
Tiwari Ajay, Khandelwal Kanak
Procedia Computer Science. 2020 173 p.56
Vegetation Mortality within Natural Wildfire Events in the Western Canadian Boreal Forest: What Burns and Why?
Ferster Colin,
Eskelson Bianca,
Andison David, LeMay Valerie
Forests. 2016 7(12). p.187
Boreal Fire Effects on Subsistence Resources in Alaska and Adjacent Canada
Nelson Joanna L.,
Zavaleta Erika S., Chapin F. Stuart
Ecosystems. 2008 11(1). p.156
Quantifying fire severity, carbon, and nitrogen emissions in Alaska's boreal forest
Boby Leslie A.,
Schuur Edward A. G.,
Mack Michelle C.,
Verbyla David, Johnstone Jill F.
Ecological Applications. 2010 20(6). p.1633
Historical and projected trends in landscape drivers affecting carbon dynamics in Alaska
Pastick Neal J.,
Duffy Paul,
Genet Hélène,
Rupp T. Scott,
Wylie Bruce K.,
Johnson Kristofer D.,
Jorgenson M. Torre,
Bliss Norman,
McGuire A. David,
Jafarov Elchin E., Knight Joseph F.
Ecological Applications. 2017 27(5). p.1383
Changes in surface albedo after fire in boreal forest ecosystems of interior Alaska assessed using MODIS satellite observations
Lyons Evan A.,
Jin Yufang, Randerson James T.
Journal of Geophysical Research: Biogeosciences. 2008 113(G2).
Increasing Wildfire in Alaska's Boreal Forest: Pathways to Potential Solutions of a Wicked Problem
Chapin F. Stuart,
Trainor Sarah F.,
Huntington Orville,
Lovecraft Amy L.,
Zavaleta Erika,
Natcher David C.,
McGuire A. David,
Nelson Joanna L.,
Ray Lily,
Calef Monika,
Fresco Nancy,
Huntington Henry,
Rupp T. Scott,
DeWilde La'ona, Naylor Rosamond L.
BioScience. 2008 58(6). p.531
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Duncan Brean W.,
Shao Guofan, Adrian Frederic W.
Forest Ecology and Management. 2009 258(2). p.132
The influence of burn severity on postfire vegetation recovery and albedo change during early succession in North American boreal forests
Jin Yufang,
Randerson James T.,
Goetz Scott J.,
Beck Pieter S. A.,
Loranty Michael M., Goulden Michael L.
Journal of Geophysical Research: Biogeosciences. 2012 117(G1).
Improved fire severity mapping in the North American boreal forest using a hybrid composite method
Holsinger Lisa M.,
Parks Sean A.,
Saperstein Lisa B.,
Loehman Rachel A.,
Whitman Ellen,
Barnes Jennifer,
Parisien Marc‐André,
Disney Mat, Bohlman Stephanie
Remote Sensing in Ecology and Conservation. 2022 8(2). p.222
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JOHNSTONE JILL F.,
HOLLINGSWORTH TERESA N.,
CHAPIN F. STUART, MACK MICHELLE C.
Global Change Biology. 2010 16(4). p.1281
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Won Myoungsoo,
Kim Kyongha, Lee Sangwoo
Korean Journal of Agricultural and Forest Meteorology. 2014 16(2). p.114
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Wu Zhiwei,
He Hong S.,
Liang Yu,
Cai Longyan, Lewis Bernard J.
Environmental Management. 2013 52(4). p.821
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Won Myoung-Soo,
Kim You-Seung, Kim Kyong-Ha
Journal of the Korean Association of Geographic Information Studies. 2014 17(3). p.54
Burn severity influences postfire CO2exchange in arctic tundra
Rocha Adrian V., Shaver Gaius R.
Ecological Applications. 2011 21(2). p.477
