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International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
RESEARCH ARTICLE

Using Landsat data to assess fire and burn severity in the North American boreal forest region: an overview and summary of results

Nancy H. F. French A G , Eric S. Kasischke B , Ronald J. Hall C , Karen A. Murphy D , David L. Verbyla E , Elizabeth E. Hoy B and Jennifer L. Allen F
+ Author Affiliations
- Author Affiliations

A Michigan Tech Research Institute, Michigan Technological University, 3600 Green Court, Suite 100, Ann Arbor, MI 48105, USA.

B Department of Geography, University of Maryland, 2181 LeFrak Hall, College Park, MD 20742, USA.

C Natural Resources Canada, Canadian Forest Service, 5320 122nd Street, Edmonton, AB, T6H 3S5, Canada.

D US Fish and Wildlife Service, National Wildlife Refuge System, 1011 E Tudor Road MS221, Anchorage, AK 99503, USA.

E Department of Forest Science, University of Alaska, Fairbanks, AK 99775, USA.

F National Park Service, Fairbanks Administrative Office, 4175 Geist Road, Fairbanks, AK 99709, USA.

G Corresponding author. Email: nancy.french@mtu.edu

International Journal of Wildland Fire 17(4) 443-462 https://doi.org/10.1071/WF08007
Submitted: 18 January 2008  Accepted: 9 July 2008   Published: 6 August 2008

Abstract

There has been considerable interest in the recent literature regarding the assessment of post-fire effects on forested areas within the North American boreal forest. Assessing the physical and ecological effects of fire in boreal forests has far-reaching implications for a variety of ecosystem processes – such as post-fire forest succession – and land management decisions. The present paper reviews past assessments and the studies presented in this special issue that have largely been based on the Composite Burn Index and differenced Normalized Burn Ratio (dNBR). Results from relating and mapping fire/burn severity within the boreal region have been variable, and are likely attributed, in part, to the wide variability in vegetation and terrain conditions that are characteristic of the region. Satellite remote sensing of post-fire effects alone without proper field calibration should be avoided. A sampling approach combining field and image values of burn condition is necessary for successful mapping of fire/burn severity. Satellite-based assessments of fire/burn severity, and in particular dNBR and related indices, need to be used judiciously and assessed for appropriateness based on the users’ need. Issues unique to high latitudes also need to be considered when using satellite-derived information in the boreal forest region.


Acknowledgements

Dr French was supported under grant NNG04GR24G from the NASA New Investigator Program. Other authors were supported with funding provided by the Bonanza Creek Long-term Ecological Research Program (funded jointly by National Science Foundation (NSF) grant DEB-0423442 and USDA Forest Service, Pacific Northwest Research Station grant PNW01-JV11261952–231), by NASA through grants NNG04GD25G and NNG04GR24G, the Joint Fire Science Program, and by the Canadian Space Agency, which funded the Canadian burn severity activity. Review comments by J. Freeburn, Natural Resources Canada, Canadian Forest Service, on an earlier version of this manuscript and additions suggested by two anonymous reviewers are greatly appreciated.


References


Alleaume S, Hely C, Le Roux J, Korontzi S, Swap RJ, Shugart HH , Justice CO (2005) Using MODIS to evaluate heterogeneity of biomass burning in southern African savannahs: a case study. International Journal of Remote Sensing  26, 4219–4237.
Crossref | GoogleScholarGoogle Scholar | BLM (2005) 2004 Alaska Fires Spring 2005 Assessment, Burned Area Rehabilitation Plan Addendum. BLM Northern Field Office. (Fairbanks, AK)

Bobbe T, Finco MV, Quayle B, Lannom K, Sohlberg R, Parsons A (2003) Field measurements for the training and validation of burn severity maps from spaceborne, remotely sensed imagery. USDA Forest Service, Final Project Report, Joint Fire Science Program-2001–2. (Salt Lake City, UT)

Bond-Lamberty B, Peckham SD, Ahl DE , Gower ST (2007) Fire as the dominant driver of central Canadian boreal forest carbon balance. Nature  450, 89–93.
Crossref | GoogleScholarGoogle Scholar | PubMed | Chapin FSIII, Viereck LA, Adams PC, Van Cleve K, Fastie CL, Ott RA, Mann D, Johnstone JF (2006) Successional processes in the Alaskan Boreal Forest. In ‘Alaska’s Changing Boreal Forest’. (Eds FS Chapin, III, MW Oswood, K Van Cleve, LA Viereck, DL Verbyla) Ch. 7, pp. 100–120. (Oxford University Press: New York)

Chuvieco E, Riaño D, Danson FM , Martin P (2006) Use of a radiative transfer model to simulate the post-fire spectral response to burn severity. Journal of Geophysical Research  111, G04S09..
Crossref | GoogleScholarGoogle Scholar | Eidenshink J, Schwind B, Brewer K, Zhu Z-L, Quayle B, Howard S (2007) A project for monitoring trends in burn severity. Fire Ecology 3, 3–21. Available at http://www.fireecology.net/pages/76 [Verified 22 July 2008]

Epting J, Verbyla D , Sorbel B (2005) Evaluation of remotely sensed indices for assessing burn severity in interior Alaska using Landsat TM and ETM+. Remote Sensing of Environment  96, 328–339.
Crossref | GoogleScholarGoogle Scholar | Gong P, Xu B (2003) Remote sensing of forests over time. In ‘Remote Sensing of Forest Environments: Concepts and Case Studies’. (Eds MA Wulder, SE Franklin) pp. 301–333. (Kluwer Academic Publishers: Boston, MA)

Gonzalez-Alonso F, Merino-De-Miguel S, Roldan-Zamarron A, Garcia-Gigorro S , Cuevas JM (2007) MERIS full resolution data for mapping level-of-damage caused by forest fires: the Valencia de Alcantara event in August 2003. International Journal of Remote Sensing  28, 797–809.
Crossref | GoogleScholarGoogle Scholar | Hinzman LD, Viereck LA, Adams PC, Romanovsky VE, Yoshikawa K (2006) Climate and permafrost dynamics of the Alaskan boreal forest. In ‘Alaska’s Changing Boreal Forest’. (Eds FS Chapin, III, MW Oswood, K Van Cleve, LA Viereck, DL Verbyla) Ch. 4, pp. 39–61. (Oxford University Press: New York)

Holden ZA, Morgan P, Crimmins MA, Steinhorst RK , Smith AMS (2007) Fire season precipitation variability influences fire extent and severity in a large south-western wilderness area, United States. Geophysical Research Letters  34, L16708.
Crossref | GoogleScholarGoogle Scholar | Hudak AT, Robichaud PR, Evans JB, Clark J, Lannom K, Morgan P, Stone C (2004) Field validation of Burned Area Reflectance Classification (BARC) products for post-fire assessment In. In ‘Proceedings 10th Biennial USDA Forest Service Remote Sensing Applications Conference, Remote Sensing for Field Users’, Salt Lake City, UT. On CD-ROM. (American Society for Photogrammetry and Remote Sensing)

Hudak AT, Morgan P, Bobbitt MJ, Smith AMS, Lewis SA, Lentile LB, Robichaud PR, Clark JT, McKinley RA (2007) The relationship of multispectral satellite imagery to immediate fire effects. Journal of Fire Ecology 3, 64–90. Available at http://www.fireecology.net/pages/76 [Verified 22 July 2008]

Hyde K, Woods WW , Donahue J (2007) Predicting gully rejuvenation after wildfire using remotely sensed burn severity data. Geomorphology  86, 496–511.
Crossref | GoogleScholarGoogle Scholar | Johnson EA (1992) ‘Fire and Vegetation Dynamics: Studies from the North American Boreal Forest.’ (Cambridge University Press: Cambridge, UK)

Johnstone JF , Chapin FS (2003) Non-equilibrium succession dynamics indicate continued northward migration of lodgepole pine. Global Change Biology  9, 1401–1409.
Crossref | GoogleScholarGoogle Scholar | Kasischke ES, Rupp TS, Verbyla DL (2005b) Fire trends in the Alaskan boreal forest region. In ‘Alaska’s Changing Boreal Forest’. (Eds FS Chapin, III, M Oswood, K Van Cleve, LA Viereck, DL Verbyla) pp. 285–301. (Oxford University Press: Cambridge, MA)

Kasischke ES, Turetsky MR, Ottmar RD, French NHF, Hoy EE , Kane ES (2008) Evaluation of the composite burn index for assessing fire severity in Alaskan black spruce forests. International Journal of Wildland Fire  17, 515–526.
Crossref | GoogleScholarGoogle Scholar | Key CH, Benson NC (2006) Landscape assessment: ground measure of severity, the Composite Burn Index, and remote sensing of severity, the Normalized Burn Index. In ‘FIREMON: Fire Effects Monitoring and Inventory System’. (Eds DC Lutes, RE Keane, JF Caratti, CH Key, NC Benson, S Sutherland, LJ Gangi) USDA Forest Service, Rocky Mountain Research Station, General Technical Report RMRS-GTR-164-CD: LA1–51. (Ogden, UT)

Keyser TL, Smith KW, Lentile LB , Sheppard WD (2006) Modeling post-fire mortality of ponderosa pine following a mixed-severity wildfire in the Black Hills: the role of tree morphology and direct fire effects. Forest Science  52, 530–539.
Lewis SA, Lentile LB, Hudak AT, Robichaud PR, Morgan P, Bobbitt MJ (2007) Mapping ground cover using hyperspectral remote sensing after the 2003 Simi and Old wildfires in Southern California. Journal of Fire Ecology 3, 109–128. Available at http://www.fireecology.net/pages/76 [Verified 21 July 2008]

Lopez-Garcia MJ , Caselles V (1991) Mapping burns and natural reforestation using Thematic Mapper data. Geocarto International  6, 31–37.
Peterson JL (1987) Analysis and reduction of the errors of predicting prescribed burn emissions. Master’s thesis, University of Washington, Seattle.

Robichaud PR, Lewis SA, Laes DYM, Hudad AT, Kokaly RF , Zamudio JA (2007) Post-fire soil burn severity mapping with hyperspectral image unmixing. Remote Sensing of Environment  108, 467–480.
Crossref | GoogleScholarGoogle Scholar | Sorbel B, Allen J (2005) Space-based burn severity mapping in Alaska’s National Parks. Alaska Park Science 4, 4–11. Available at http://www.nps.gov/akso/AKParkScience/Winter2005/Winter2005index.htm [Verified 22 July 2008]

Stocks BJ, Mason JA, Todd JB, Bosch EM, Wotton BM, Amiro BD, Flannigan MD, Hirsch KG, Logan KA, Martell DL , Skinner WR (2002) Large forest fires in Canada, 1959–1997. Journal of Geophysical Research  107, 8149.
Crossref | GoogleScholarGoogle Scholar | Van Cleve K, Chapin FSIII, Flanagan PW, Viereck LA, Dyrness CT (1986) ‘Forest Ecosystems in the Alaskan Taiga.’ (Springer-Verlag: New York)

van Wagtendonk JW, Root RR , Key CH (2004) Comparison of AVIRIS and Landsat ETM+ detection capabilities for burn severity. Remote Sensing of Environment  92, 397–408.
Crossref | GoogleScholarGoogle Scholar | Viereck LA (1983) The effects of fire in black spruce ecosystems of Alaska and northern Canada. In ‘The Role of Fire in Northern Circumpolar Ecosystems’. (Eds RW Wein, DA MacLean) pp. 201–220. (Wiley: Chichester, UK)

Walz Y, Maier SW, Dech SW, Conrad C , Colditz RR (2007) Classification of burn severity using Moderate Resolution Imaging Spectroradiometer (MODIS): a case study in the jarrah-marri forest of south-west Western Australia. Journal of Geophysical Research  112, G02002..
Crossref | GoogleScholarGoogle Scholar | Zhu Z, Key C, Ohlen D, Benson N (2006) Evaluate sensitivities of burn-severity mapping algorithms for different ecosystems and fire histories in the United States. US Department of Interior, Final Report to the Joint Fire Science Program: Project JFSP 01–1-4–12. (Sioux Falls, SD)

Zoltai SC, Morrissey LA, Livingstone GP , de Groot WJ (1998) Effects of fires on carbon cycling in North American peatlands. Environmental Review  6, 13–24.
Crossref | GoogleScholarGoogle Scholar |