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

Remote sensing of fire severity in the Blue Mountains: influence of vegetation type and inferring fire intensity

Kate A. Hammill A B and Ross A. Bradstock A
+ Author Affiliations
- Author Affiliations

A Biodiversity Conservation Science Section, Department of Environment and Conservation (NSW), PO Box 1967, Hurstville, NSW 2220, Australia.

B Corresponding author. Email: kate.hammill@environment.nsw.gov.au

International Journal of Wildland Fire 15(2) 213-226 https://doi.org/10.1071/WF05051
Submitted: 27 April 2005  Accepted: 2 March 2006   Published: 31 May 2006

Abstract

Fire intensity affects ecological and geophysical processes in fire-prone landscapes. We examined the potential for satellite imagery (Satellite Pour l’Observation de la Terre [SPOT2] and Landsat7) to detect and map fire severity patterns in a rugged landscape with variable vegetation near Sydney, Australia. A post-fire, vegetation-based indicator of fire intensity (burnt shrub branch tip diameters, representing the size of fuel consumed) was also used to explore whether fire severity patterns can be used to retrospectively infer patterns of fire intensity. Six severity classes (ranging from unburnt to complete crown consumption) were defined using aerial photograph interpretation and a field assessment across five vegetation types of varying height and complexity (sedge-swamp, heath, woodland, open forest, and tall forest). Using established Normalised Difference Vegetation Index (NDVI) differencing methodology, SPOT2 and Landsat7 imagery yielded similar broad-scale severity patterns across the study area. This was despite differences in image resolution (10 m and 30 m, respectively) and capture dates (2 months and 9 months apart, respectively). However, differences in the total areas mapped for some severity classes were found. In particular, there was reduced differentiation between unburnt and low-severity areas and between crown-scorched and crown-consumed areas when using the Landsat7 data. These differences were caused by fine-scale classification anomalies and were most likely associated with seasonal differences in vegetation condition (associated with time of image capture), post-fire movement of ash, resprouting of vegetation, and low sun elevation. Relationships between field severity class and NDVIdifference values revealed that vegetation type does influence the detection of fire severity using these types of satellite data: regression slopes were greater for woodland, forest, and tall forest data than for sedge-swamp and heath data. The effect of vegetation type on areas mapped in each fire severity class was examined but found to be minimal in the present study due to the uneven distribution of vegetation types in the study area (woodland and open forest cover 86% of the landscape). Field observations of burnt shrub branch tips, which were used as a surrogate for fire intensity, revealed that relationships between fire severity and fire intensity are confounded by vegetation type (mainly height). A method for inferring fire intensity from remotely sensed patterns of fire severity was proposed in which patterns of fire severity and vegetation type are combined.


References


Alexander ME (1982) Calculating and interpreting forest fire intensities. Canadian Journal of Botany  60, 349–357.
Byram GM (1959) Combustion of forest fuels. In ‘Forest fire: control and use’. (Ed. KP Davis) pp. 61–89. (McGraw-Hill: New York)

Catchpole W (2002) Fire properties and burn patterns in heterogeneous landscapes. In ‘Flammable Australia, the fire regimes and biodiversity of a continent’. (Eds RA Bradstock, JE Williams, AM Gill) pp. 49–75. (Cambridge University Press: Cambridge, UK)

Catling PC, Coops NC , Burt RJ (2001) The distribution and abundance of ground-dwelling mammals in relation to time since wildfire and vegetation structure in south-eastern Australia. Wildlife Research  28, 555–564.
Crossref | GoogleScholarGoogle Scholar | Cheney NP (1981) Fire behaviour. In ‘Fire and the Australian biota’. (Eds AM Gill, RH Groves, IR Noble) pp. 151–175. (Australian Academy of Science: Canberra, Australia)

Clark JS, Gill AM, Kershaw AP (2002) Spatial variability in fire regimes: its effects on recent and past vegetation. In ‘Flammable Australia, the fire regimes and biodiversity of a continent’. (Eds RA Bradstock, JE Williams, AM Gill) pp. 125–141. (Cambridge University Press: Cambridge, UK)

Clarke PJ (2002) Habitat islands in fire-prone vegetation: do landscape features influence community composition. Journal of Biogeography  29, 677–684.
Crossref | GoogleScholarGoogle Scholar | Feller MC (1998) The influence of fire severity, not fire intensity, on understorey vegetation biomass in British Columbia. In ‘Proceedings of the 13th fire and forest meteorology conference. Lorne, Australia 1996’. (Ed. R Weber) pp. 335–348. (International Association of Wildland Fire: Fairfax, VA, USA)

Franklin SE, Hall RJ, Smith L , Gerylo GR (2003) Discrimination of conifer height, age and crown closure classes using Landsat-5 TM imagery in the Canadian Northwest Territories. International Journal of Remote Sensing  24, 1823–1834.
Crossref | GoogleScholarGoogle Scholar | Gill AM (1981) Adaptive responses of Australian vascular plant species to fires. In ‘Fire and the Australian biota’. (Eds AM Gill, RH Groves, IR Noble) pp. 243–271. (Australian Academy of Science: Canberra, Australia)

Gill AM, Bradstock RA (2003) Fire regimes and biodiversity: a set of postulates. In ‘Australia burning: fire ecology, policy and management issues’. (Eds G Cary, D Lindenmayer, S Dovers) pp. 15–25. (CSIRO Publishing: Melbourne)

Gill AM, Allan G , Yates C (2003) Fire-created patchiness in Australian savannas. International Journal of Wildland Fire  12, 323–331.
Crossref | GoogleScholarGoogle Scholar | Keith DA, McCaw WL, Whelan RJ (2002) Fire regimes in Australian heathlands and their effects on plants and animals. In ‘Flammable Australia, the fire regimes and biodiversity of a continent’. (Eds RA Bradstock, JE Williams, AM Gill) pp. 199–237. (Cambridge University Press: Cambridge, UK)

Key CH, Benson NC (1999) ‘The composite burn index (CBI): field rating of burn severity.’ US Geological Survey. Available at http://nrmsc.usgs.gov/research/cbi.htm [Verified 3 April 2006]

Lunetta RS, Congalton RG, Fenstermaker LK, Jensen JR, McGwier KC, Tinney LR (1994) Remote sensing and geographic information system data integration: error sources and research issues. In ‘Remote sensing thematic accuracy assessment: a compendium’. (Ed. LK Fenstermaker) pp. 335–347. (American Society for Photogrammetry and Remote Sensing: Bethesda, MD, USA)

McArthur AG (1967) ‘Fire behaviour in eucalypt forests.’ Leaflet no. 7. (Forest Research Institute, Forest and Timber Bureau of Australia: Canberra)

Milne AK (1986) The use of remote sensing in mapping and monitoring vegetational change associated with bushfires events in eastern Australia. Geocarto International  1, 25–32.
Pickett JW, Alder JD (1997) ‘Layers of time: the Blue Mountains and their geology.’ (New South Wales Department of Mineral Resources: Sydney)

Price O, Russell-Smith J , Edwards A (2003) Fine-scale patchiness of different fire intensities in sandstone heath in northern Australia. International Journal of Wildland Fire  12, 227–236.
Crossref | GoogleScholarGoogle Scholar | Tindall D, Pennay C, Tozer MG, Turner K, Keith DA (2004) ‘Native vegetation map report series. No. 4. Araluen, Batemans Bay, Braidwood, Burragorang, Goulburn, Jervis Bay, Katoomba, Kiama, Moss Vale, Penrith, Port Hacking, Sydney, Taralga, Ulladulla, Wollongong.’ (NSW Department of Environment and Conservation and NSW Department of Infrastructure, Planning and Natural Resources: Sydney)

Treitz PM, Howarth PJ, Suffling RC (1994) Application of detailed ground information to vegetation mapping with high spatial resolution digital imagery. In ‘Remote sensing thematic accuracy assessment: a compendium’. (Ed. LK Fenstermaker) pp. 355–372. (American Society for Photogrammetry and Remote Sensing: Bethesda, MD)

Turner MG, Hargrove WW, Gardner RH , Romme WH (1994) Effects of fire on landscape heterogeneity in Yellowstone National Park, Wyoming. Journal of Vegetation Science  5, 731–742.

Crossref | Van Loon AP (1977) ‘Bushland fuel quantities in the Blue Mountains: litter and understorey.’ Research Note No. 33. (Forestry Commission of NSW, Sydney.)

Whelan RJ, Rodgerson L, Dickman CR, Sutherland EF (2002) Critical lifecycles of plants and animals: developing a process-based understanding of population changes in fire-prone landscapes. In ‘Flammable Australia, the fire regimes and biodiversity of a continent’. (Eds RA Bradstock, JE Williams, AM Gill) pp. 94–124. (Cambridge University Press: Cambridge, UK)

Whight S , Bradstock RA (1999) Indices of fire characteristics in sandstone heath near Sydney, Australia. International Journal of Wildland Fire  9, 145–153.
Crossref | GoogleScholarGoogle Scholar | Zar JH (1974) ‘Biostatistical analysis.’ (Prentice-Hall: Englewood Cliffs, NJ)