Predicting continuous variation in forest fuel load using biophysical models: a case study in south-eastern Australia
Thomas J. Duff A C , Tina L. Bell B and Alan York AA Forest and Fire Ecology Group, Department of Forest and Ecosystem Science, The University of Melbourne, Water Street, Creswick, Vic. 3363, Australia.
B Faculty of Agriculture and Environment, University of Sydney, Biomedical Building, 1 Central Avenue, Australian Technology Park, Eveleigh NSW 2015, Australia.
C Corresponding author. Email: tjduff@unimelb.edu.au
International Journal of Wildland Fire 22(3) 318-332 https://doi.org/10.1071/WF11087
Submitted: 27 June 2011 Accepted: 12 July 2012 Published: 3 October 2012
Abstract
The increasing potential for wildfires in Mediterranean-type landscapes has resulted in pressure to mitigate fire threats. This is typically achieved by strategic reduction of fuel. To prioritise fuel management, it is necessary to understand vegetation dynamics and the relationships between plants and fuel. As the direct measurement of fuel in the field is labour intensive, mapped vegetation classes are typically used as to estimate fuel load. As vegetation properties vary continuously, the error in such estimates can be high. Remotely sensed and biophysical data are commonly used for vegetation classification, but rarely for estimating fuel load. This study investigated how fuel load varied with vegetation composition in an Australian woodland and assessed the potential for using biophysical models to create continuous estimates. Fuel was found to be influenced by species abundance, with some species having a greater contribution to load than others. Fuel was found to be somewhat predictable, with quantities related to fire history and several other biophysical variables. Models were applied to create continuous maps of fuel load; these provided a more precise representation of fuel variation than using discrete classes. Improved maps have the potential to facilitate improved prediction of fire behaviour and assist targeted fuel management.
Additional keywords: bark, burning, bushfire, continuum, elevated fuel, Generalised Additive Model, litter, wildfire, wildland fire.
References
Accad A, Neil DT (2006) Modelling pre-clearing vegetation distribution using GIS-integrated statistical, ecological and data models: a case study from the wet tropics of northeastern Australia. Ecological Modelling 198, 85–100.| Modelling pre-clearing vegetation distribution using GIS-integrated statistical, ecological and data models: a case study from the wet tropics of northeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Anderson HE (1982) Aids to determining fuel models for fire behaviour. USDA Forest Service, Intermountain Forest and Range Experiment Station, General Technical Report INT-122. (Ogden, UT)
Anjos RM, Macario K, Veiga R, Carvalho C, Mosquera B (2007) Radiometric analyses of beach sands from the southeast of Brazil. AIP Conference Proceedings 884, 249–253.
| Radiometric analyses of beach sands from the southeast of Brazil.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2sXjslaks7k%3D&md5=d96f54a6a46aca7a0f9f4b9d180e8563CAS |
Armour CD, Bunting SC, Neuenschwander LF (1984) Fire intensity effects on the understorey in ponderosa pine forests. Journal of Range Management 37, 44–49.
| Fire intensity effects on the understorey in ponderosa pine forests.Crossref | GoogleScholarGoogle Scholar |
Arroyo LA, Pascual C, Manzanera JA (2008) Fire models and methods to map fuel types: the role of remote sensing. Forest Ecology and Management 256, 1239–1252.
| Fire models and methods to map fuel types: the role of remote sensing.Crossref | GoogleScholarGoogle Scholar |
Austin MP, Smith TM (1989) A new model for the continuum concept. Plant Ecology 83, 35–47.
| A new model for the continuum concept.Crossref | GoogleScholarGoogle Scholar |
Baeza M, Raventós J, Escarré A, Vallejo V (2006) Fire risk and vegetation structural dynamics in Mediterranean shrubland. Plant Ecology 187, 189–201.
| Fire risk and vegetation structural dynamics in Mediterranean shrubland.Crossref | GoogleScholarGoogle Scholar |
Birk EM, Simpson RW (1980) Steady state and the continuous input model of litter accumulation and decomposition in Australian eucalypt forests. Ecology 61, 481–485.
| Steady state and the continuous input model of litter accumulation and decomposition in Australian eucalypt forests.Crossref | GoogleScholarGoogle Scholar |
Boer MM, Sadler RJ, Wittkuhn RS, McCaw L, Grierson PF (2009) Long-term impacts of prescribed burning on regional extent and incidence of wildfires: evidence from 50 years of active fire management in SW Australian forests. Forest Ecology and Management 259, 132–142.
| Long-term impacts of prescribed burning on regional extent and incidence of wildfires: evidence from 50 years of active fire management in SW Australian forests.Crossref | GoogleScholarGoogle Scholar |
Bonham CD (1989) ‘Measurements for Terrestrial Vegetation.’ (Wiley: New York)
Brandis K, Jacobson C (2003) Estimation of vegetative fuel loads using Landsat TM imagery in New South Wales, Australia. International Journal of Wildland Fire 12, 185–194.
| Estimation of vegetative fuel loads using Landsat TM imagery in New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |
Brzeziecki B, Kienast F, Wildi O (1995) Modelling potential impacts of climate change on the spatial distribution of zonal forest communities in Switzerland. Journal of Vegetation Science 6, 257–268.
| Modelling potential impacts of climate change on the spatial distribution of zonal forest communities in Switzerland.Crossref | GoogleScholarGoogle Scholar |
Byram GM (1959) Combustion of forest fuels. In ‘Forest Fire: Control and Use’. (Ed. KP Davis) pp. 61–89. (McGraw Hill Book Company Inc.: New York)
Cameron PA, Mitra B, Fitzgerald M, Scheinkestel CD, Stripp A, Batey C, Niggemeyer L, Truesdale M, Holman P, Mehra R, Wasiak J, Cleland H (2009) Black Saturday: the immediate impact of the February 2009 bushfires in Victoria, Australia. The Medical Journal of Australia 191, 11–16.
Campbell C, Blair S, Wilson A (2010) Adaptive management of fire: the role of a learning network. Department of Sustainability and Environment, Victoria. (Melbourne)
Cingolani AM, Renison D, Tecco PA, Gurvich DE, Cabido M (2008) Predicting cover types in a mountain range with long evolutionary grazing history: a GIS approach. Journal of Biogeography 35, 538–551.
| Predicting cover types in a mountain range with long evolutionary grazing history: a GIS approach.Crossref | GoogleScholarGoogle Scholar |
Department for Environment and Heritage (2008) Overall Fuel Hazard Guide for South Australia. Department for Environment and Heritage, South Australia. (Adelaide, SA)
Department of Sustainability and Environment (2004a) Glenelg Plain bioregion; EVC 48: heathy woodland. Department of Sustainability and Environment, Victoria. (Melbourne)
Department of Sustainability and Environment (2004b) Portland fire protection plan. Department of Sustainability and Environment, Victoria. (Melbourne)
Dodson JR (2001) Holocene vegetation change in the Mediterranean-type climate regions of Australia. The Holocene 11, 673–680.
| Holocene vegetation change in the Mediterranean-type climate regions of Australia.Crossref | GoogleScholarGoogle Scholar |
Domenikiotis C, Dalezios NR, Loukas A, Karteris M (2002) Agreement assessment of NOAA/AVHRR NDVI with Landsat TM NDVI for mapping burned forested areas. International Journal of Remote Sensing 23, 4235–4246.
| Agreement assessment of NOAA/AVHRR NDVI with Landsat TM NDVI for mapping burned forested areas.Crossref | GoogleScholarGoogle Scholar |
Fernandes PM (2009) Combining forest structure data and fuel modelling to classify fire hazard in Portugal. Annals of Forest Science 66, 415
| Combining forest structure data and fuel modelling to classify fire hazard in Portugal.Crossref | GoogleScholarGoogle Scholar |
Fernandes PM, Botelho HS (2003) A review of prescribed burning effectiveness in fire hazard reduction. International Journal of Wildland Fire 12, 117–128.
| A review of prescribed burning effectiveness in fire hazard reduction.Crossref | GoogleScholarGoogle Scholar |
Finney MA, Sapsis DB, Bahro B (2002) Use of FARSITE for simulating fire supression and analyzing fuel treatment economics. In ‘Proceedings of the Conference on Fire in California Ecosystems: Integrating Ecology, Prevention and Management’, 17-20 November 1997, San Diego, CA. (Eds NG Sugihara, ME Morales, TJ Morales) pp. 121–136. (Association for Fire Ecology: Eugene, OR)
Fox BJ, Fox MD, McKay GM (1979) Litter accumulation after fire in a eucalypt forest. Australian Journal of Botany 27, 157–165.
| Litter accumulation after fire in a eucalypt forest.Crossref | GoogleScholarGoogle Scholar |
Fraser RH, Li Z (2002) Estimating fire-related parameters in boreal forest using SPOT VEGETATION. Remote Sensing of Environment 82, 95–110.
| Estimating fire-related parameters in boreal forest using SPOT VEGETATION.Crossref | GoogleScholarGoogle Scholar |
Fuller M (1991) ‘Forest Fires: an Introduction to Wildland Fire Behaviour, Management, Firefighting and Prevention.’ (Wiley: New York)
Gallant JC, Dowling TI (2003) A multiresolution index of valley bottom flatness for mapping depositional areas. Water Resources Research 39, 1347–1353.
| A multiresolution index of valley bottom flatness for mapping depositional areas.Crossref | GoogleScholarGoogle Scholar |
Gibbons FR, Downes RG (1964) ‘A study of the land in south western Victoria.’ (Soil Conservation Authority, Victoria: Melbourne)
Gould JS, McCaw WL, Cheney NP, Ellis PF, Matthews S (2007) ‘Field Guide – Fuel Assessment and Fire Behaviour Prediction in Dry Eucalypt Forest.’ (Ensis–CSIRO: Canberra, ACT; and WA Department of Environment and Conservation: Perth, WA)
Gould JS, Lachlan McCaw W, Phillip Cheney N (2011) Quantifying fine fuel dynamics and structure in dry eucalypt forest (Eucalyptus marginata) in Western Australia for fire management. Forest Ecology and Management 262, 531–546.
| Quantifying fine fuel dynamics and structure in dry eucalypt forest (Eucalyptus marginata) in Western Australia for fire management.Crossref | GoogleScholarGoogle Scholar |
Groves R, Hocking P, Mcmahon A (1986) Distribution of biomass, nitrogen, phosphorus and other nutrients in Banksia marginata and B. ornata shoots of different ages after fire. Australian Journal of Botany 34, 709–725.
| Distribution of biomass, nitrogen, phosphorus and other nutrients in Banksia marginata and B. ornata shoots of different ages after fire.Crossref | GoogleScholarGoogle Scholar |
Guisan A, Zimmermann NE (2000) Predictive habitat distribution models in ecology. Ecological Modelling 135, 147–186.
| Predictive habitat distribution models in ecology.Crossref | GoogleScholarGoogle Scholar |
Guisan A, Theurillat JP, Kienast F (1998) Predicting the potential distribution of plant species in an alpine environment. Journal of Vegetation Science 9, 65–74.
| Predicting the potential distribution of plant species in an alpine environment.Crossref | GoogleScholarGoogle Scholar |
Hennessy K, Lucas C, Nicholls N, Bathols J, Suppiah R, Ricketts J (2005) Climate change impacts on fire-weather in south-east Australia. CSIRO Marine and Atmospheric Research. (Melbourne)
Jacobson CR (2010) Use of linguistic estimates and vegetation indices to assess post-fire vegetation regrowth in woodland areas. International Journal of Wildland Fire 19, 94–103.
| Use of linguistic estimates and vegetation indices to assess post-fire vegetation regrowth in woodland areas.Crossref | GoogleScholarGoogle Scholar |
Keane RE, Mincemoyer SA, Schmidt KM, Long DG, Garner JL (2000) Mapping vegetation and fuels for fire management on the Gila National Forest Complex, New Mexico. USDA Forest Service, Rocky Mountain Research Station, General Technical Report RMRS-GTR-46-CD. (Missoula, MT)
Keane RE, Burgan R, van Wagtendonk J (2001) Mapping wildland fuels for fire management across multiple scales: integrating remote sensing, GIS and biophysical modelling. International Journal of Wildland Fire 10, 301–319.
| Mapping wildland fuels for fire management across multiple scales: integrating remote sensing, GIS and biophysical modelling.Crossref | GoogleScholarGoogle Scholar |
Keeley JE, Safford H, Fotheringham CJ, Franklin J, Moritz M (2009) The 2007 Southern California wildfires: lessons in complexity. Journal of Forestry 107, 287–296.
Kessell SR (1977) Gradient modeling: a new approach to fire modeling and wilderness resource management. Environmental Management 1, 39–48.
| Gradient modeling: a new approach to fire modeling and wilderness resource management.Crossref | GoogleScholarGoogle Scholar |
King KJ, Cary GJ, Bradstock RA, Chapman J, Pyrke A, Marsden-Smedley JB (2006) Simulation of prescribed burning strategies in south-west Tasmania, Australia: effects on unplanned fires, fire regimes and ecological management values. International Journal of Wildland Fire 15, 527–540.
| Simulation of prescribed burning strategies in south-west Tasmania, Australia: effects on unplanned fires, fire regimes and ecological management values.Crossref | GoogleScholarGoogle Scholar |
King KJ, Bradstock RA, Cary GJ, Chapman J, Marsden-Smedley JB (2008) The relative importance of fine-scale fuel mosaics on reducing fire risk in south-west Tasmania, Australia. International Journal of Wildland Fire 17, 421–430.
| The relative importance of fine-scale fuel mosaics on reducing fire risk in south-west Tasmania, Australia.Crossref | GoogleScholarGoogle Scholar |
Knox KJE, Clarke P (2006) Fire season and intensity affect shrub recruitment in temperate sclerophyllous woodlands. Oecologia 149, 730–739.
| Fire season and intensity affect shrub recruitment in temperate sclerophyllous woodlands.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD28rmtlWhtQ%3D%3D&md5=f1e9f8657d7db417995cfa788cc11005CAS |
Kurz-Besson C, Couteaux MM, Berg B, Remacle J, Ribeiro C, Romanya J, Thiery JM (2006) A climate response function explaining most of the variation of the forest floor needle mass and the needle decomposition in pine forests across Europe. Plant and Soil 285, 97–114.
| A climate response function explaining most of the variation of the forest floor needle mass and the needle decomposition in pine forests across Europe.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XpsFWmu78%3D&md5=e389e0c8d50ff5f140513e9425660d6fCAS |
Loveland TR (2001) Toward a national fuels mapping strategy: lessons from selected mapping programs. International Journal of Wildland Fire 10, 289–299.
| Toward a national fuels mapping strategy: lessons from selected mapping programs.Crossref | GoogleScholarGoogle Scholar |
Marlon JR, Bartlein PJ, Walsh MK, Harrison SP, Brown KJ, Edwards ME, Higuera PE, Power MJ, Anderson RS, Briles C, Brunelle A, Carcaillet C, Daniels M, Hu FS, Lavoie M, Long C, Minckley T, Richard PJH, Scott AC, Shafer DS, Tinner W, Umbanhowar CE, Whitlock C (2009) Wildfire responses to abrupt climate change in North America. Proceedings of the National Academy of Sciences of the United States of America 106, 2519–2524.
| Wildfire responses to abrupt climate change in North America.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXislahsrs%3D&md5=901614a3fc3bdda63bd9ae7f3f023507CAS |
Marsden-Smedley JB, Catchpole WR (1995) Fire behaviour modelling in Tasmanian buttongrass moorlands. I. fuel characteristics. International Journal of Wildland Fire 5, 203–214.
| Fire behaviour modelling in Tasmanian buttongrass moorlands. I. fuel characteristics.Crossref | GoogleScholarGoogle Scholar |
McArthur AG (1967) Fire behaviour in eucalypt forests. Forestry and Timber Bureau, Department of National Development. (Canberra, ACT)
McCarthy GJ, Tolhurst KG (2001) Effectiveness of broadscale fuel reduction burning in assisting with wildfire control in parks and forests in Victoria. Department of Natural Resources and Environment. (Melbourne)
McCarthy GJ, Tolhurst KG, Chatto K (1999) Overall fuel hazard guide. Department of Natural Resources and Environment. (Melbourne)
McCaw WL, Neal JE, Smith RH (2002) Stand characteristics and fuel accumulation in a sequence of even-aged Karri (Eucalyptus diversicolor) stands in south-west Western Australia. Forest Ecology and Management 158, 263–271.
| Stand characteristics and fuel accumulation in a sequence of even-aged Karri (Eucalyptus diversicolor) stands in south-west Western Australia.Crossref | GoogleScholarGoogle Scholar |
McMahon ARG, Carr GW, Bedgood SE, Hill RJ, Pritchard AM, Cleary DM, Cleary JP (1994) Prescribed fire and control of coast wattle (Acacia sophorae (Labill.) R.Br.) invasion in coastal heath in south-west Victoria. In ‘Proceedings of the Conference Fire and Biodiversity: the Effects and Effectiveness of Fire Management’, 8–9 October 1994, Melbourne, Vic. (Biodiversity Unit, Department of the Environment, Sport and Territories: Canberra ACT) Available at http://www.environment.gov.au/archive/biodiversity/publications/series/paper8/paper8.html [Verified 27 August 2012]
Mees R, Strauss D, Chase R (1993) Modeling wildland fire containment with uncertain flame length and fireline width. International Journal of Wildland Fire 3, 179–185.
| Modeling wildland fire containment with uncertain flame length and fireline width.Crossref | GoogleScholarGoogle Scholar |
Miller JM, Miller DM (2008) No zero left behind: comparing the fit for zero-inflation models as a function of skew and proportion of zeros. In ‘Interstat Statistics on the Internet’. (Virginia Polytechnic Institute and State University: Blacksburg, VA)
Morrison DA (2002) Effects of fire intensity on plant species composition of sandstone communities in the Sydney region. Austral Ecology 27, 433–441.
| Effects of fire intensity on plant species composition of sandstone communities in the Sydney region.Crossref | GoogleScholarGoogle Scholar |
Morrison DA, Cary GJ, Pengelly SM, Ross DG, Mullins BJ, Thomas CR, Anderson TS (1995) Effects of fire frequency on plant species composition of sandstone communities in the Sydney region: interfire interval and time since fire. Australian Journal of Ecology 20, 239–247.
| Effects of fire frequency on plant species composition of sandstone communities in the Sydney region: interfire interval and time since fire.Crossref | GoogleScholarGoogle Scholar |
Murphy BP, Russell-Smith J, Prior LD (2010) Frequent fires reduce tree growth in northern Australian savannas: implications for tree demography and carbon sequestration. Global Change Biology 16, 331–343.
| Frequent fires reduce tree growth in northern Australian savannas: implications for tree demography and carbon sequestration.Crossref | GoogleScholarGoogle Scholar |
Noble IR, Slatyer RO (1980) The use of vital attributes to predict successional changes in plant communities subject to recurrent disturbances. Vegetatio 43, 5–21.
| The use of vital attributes to predict successional changes in plant communities subject to recurrent disturbances.Crossref | GoogleScholarGoogle Scholar |
Ohmann JL, Gregory MJ, Henderson EB, Roberts HM (2011) Mapping gradients of community composition with nearest-neighbour imputation: extending plot data for landscape analysis. Journal of Vegetation Science 22, 660–676.
| Mapping gradients of community composition with nearest-neighbour imputation: extending plot data for landscape analysis.Crossref | GoogleScholarGoogle Scholar |
Olson JS (1963) Energy storage and the balance of producers and decomposers in ecological systems. Ecology 44, 322–331.
| Energy storage and the balance of producers and decomposers in ecological systems.Crossref | GoogleScholarGoogle Scholar |
Pierce KB, Ohmann JL, Wimberly MC, Gregory MJ, Fried JS (2009) Mapping wildland fuels and forest structure for land management: a comparison of nearest neighbor imputation and other methods. Canadian Journal of Forest Research 39, 1901–1916.
| Mapping wildland fuels and forest structure for land management: a comparison of nearest neighbor imputation and other methods.Crossref | GoogleScholarGoogle Scholar |
Podur J, Wotton M (2010) Will climate change overwhelm fire management capacity? Ecological Modelling 221, 1301–1309.
| Will climate change overwhelm fire management capacity?Crossref | GoogleScholarGoogle Scholar |
Pyne SJ (2008) Passing the torch: why the eons-old truce between humans and fire has burst into an age of megafires, and what can be done about it. The American Scholar 77, 22–32.
R Development Core Team (2009) R: a language and environment for statistical computing. (R Foundation for Statistical Computing: Vienna, Austria)
Rawlins BG, Lark RM, Webster R (2007) Understanding airborne radiometric survey signals across part of eastern England. Earth Surface Processes and Landforms 32, 1503–1515.
| Understanding airborne radiometric survey signals across part of eastern England.Crossref | GoogleScholarGoogle Scholar |
Reich RM, Lundquist JE, Bravo VA (2004) Spatial models for estimating fuel loads in the Black Hills, South Dakota, USA. International Journal of Wildland Fire 13, 119–129.
| Spatial models for estimating fuel loads in the Black Hills, South Dakota, USA.Crossref | GoogleScholarGoogle Scholar |
Reichenback H (1956) ‘The Direction of Time.’ (University of California Press: Berkeley, CA)
Rollins MG, Keane RE, Parsons RA (2004) Mapping fuels and fire regimes using remote sensing, ecosystem simulation, and gradient modeling. Ecological Applications 14, 75–95.
| Mapping fuels and fire regimes using remote sensing, ecosystem simulation, and gradient modeling.Crossref | GoogleScholarGoogle Scholar |
Ross JH, Walsh NG (2003) ‘A census of the vascular plants of Victoria.’ (Royal Botanic Gardens: Melbourne)
Rossiter NA, Setterfield SA, Douglas MM, Hutley LB (2003) Testing the grass-fire cycle: alien grass invasion in the tropical savannas of northern Australia. Diversity & Distributions 9, 169–176.
| Testing the grass-fire cycle: alien grass invasion in the tropical savannas of northern Australia.Crossref | GoogleScholarGoogle Scholar |
Rothermel RC (1972) A mathematical model for predicting fire spread in wildland fuels. USDA Forest Service, Intermountain Forest and Range Experiment Station, General Technical Report INT-115. (Ogden, UT)
Rothermel RC (1983) How to predict the spread and intensity of forest and range fires. USDA Forest Service, National Wildfire Coordinating Group. (Boise, ID)
Stewart D (1968) A general canonical correlation index. Psychological Bulletin 70, 160–163.
| A general canonical correlation index.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DyaF1M%2FgslSktA%3D%3D&md5=cdd7c8a09ebbe576f1661be9c15d212aCAS |
Teague B, McLeod R, Pascoe S (2010) The 2009 Victorian Bushfires Final Report. Parliament of Victoria. (Melbourne)
Teeter L (2008) Wildfire mitigation. Forest Policy and Economics 10, 341–343.
| Wildfire mitigation.Crossref | GoogleScholarGoogle Scholar |
Thaxton JM, Platt WJ (2006) Small-scale fuel variation alters fire intensity and shrub abundance in a pine savanna. Ecology 87, 1331–1337.
| Small-scale fuel variation alters fire intensity and shrub abundance in a pine savanna.Crossref | GoogleScholarGoogle Scholar |
Tolhurst KG, Cheney NP (1999) ‘Synopsis of the knowledge used in prescribed burning in Victoria.’ Department of Natural Resources and Environment. (Melbourne)
Tolhurst KG, Kellas JD, Wilson AA (1992) Low intensity fire behaviour and fuel dynamics in dry sclerophyll forest, Wombat State Forest. In ‘Ecological Impacts of Fuel Reduction Burning in Dry Sclerophyll Forest’. Forest Research, Department of Conservation and Natural Resources, Research Report Number 349. (Eds KG Tolhurst and DW Flinn) pp. 2-1–2.40. (Melbourne)
Tolhurst KG, Shields B, Chong D (2008) Phoenix: development and application of a bushfire risk management tool. Australian Journal of Emergency Management 23, 47–54.
Tymstra C, Flannigan MD, Armitage OB, Logan K (2007) Impact of climate change on area burned in Alberta’s boreal forest. International Journal of Wildland Fire 16, 153–160.
| Impact of climate change on area burned in Alberta’s boreal forest.Crossref | GoogleScholarGoogle Scholar |
Vaillant NM, Fites-Kaufman JA, Stephens SL (2009) Effectiveness of prescribed fire as a fuel treatment in Californian coniferous forests. International Journal of Wildland Fire 18, 165–175.
| Effectiveness of prescribed fire as a fuel treatment in Californian coniferous forests.Crossref | GoogleScholarGoogle Scholar |
van Leeuwen WJD, Casady GM, Neary DG, Bautista S, Alloza JA, Carmel Y, Wittenberg L, Malkinson D, Orr BJ (2010) Monitoring post-wildfire vegetation response with remotely sensed time-series data in Spain, USA and Israel. International Journal of Wildland Fire 19, 75–93.
| Monitoring post-wildfire vegetation response with remotely sensed time-series data in Spain, USA and Israel.Crossref | GoogleScholarGoogle Scholar |
Victorian Government (2008) ‘Living with fire: Victoria’s bushfire strategy.’ (The State of Victoria: Melbourne)
Walker J (1981) Fuel dynamics in Australian vegetation. In ‘Fire and the Australian Biota’. (Eds AM Gill, RH Groves, IR Noble) pp. 101–129. (Australian Academy of Science: Canberra)
Walsh NG, Entwisle TJ (1994) ‘Flora of Victoria Volume 2: Ferns and Allied Plants, Conifers and Monocotyledons.’ (Inkata Press: Melbourne)
Walsh NG, Entwisle TJ (1996) ‘Flora of Victoria Volume 3: Dicotyledons (Winteraceae to Myrtaceae).’ (Inkata Press: Melbourne)
Watson P, Wardell-Johnson G (2004) Fire frequency and time-since-fire effects on the open-forest and woodland flora of Girraween National Park, south-east Queensland, Australia. Austral Ecology 29, 225–236.
| Fire frequency and time-since-fire effects on the open-forest and woodland flora of Girraween National Park, south-east Queensland, Australia.Crossref | GoogleScholarGoogle Scholar |
Westfall JA, Woodall CW (2007) Measurement repeatability of a large-scale inventory of forest fuels. Forest Ecology and Management 253, 171–176.
| Measurement repeatability of a large-scale inventory of forest fuels.Crossref | GoogleScholarGoogle Scholar |
Williams AAJ, Karoly DJ, Tapper N (2001) The sensitivity of Australian fire danger to climate change. Climatic Change 49, 171–191.
| The sensitivity of Australian fire danger to climate change.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXktVOht7c%3D&md5=90c735c56e66b01b329fcc5043c81906CAS |
Wood SN (2008) Fast stable direct fitting and smoothness selection for generalized additive models. Journal of the Royal Statistical Society. Series B, Statistical Methodology 70, 495–518.
| Fast stable direct fitting and smoothness selection for generalized additive models.Crossref | GoogleScholarGoogle Scholar |
Zimmermann NE, Kienast F (1999) Predictive mapping of alpine grasslands in Switzerland: species versus community approach. Journal of Vegetation Science 10, 469–482.
| Predictive mapping of alpine grasslands in Switzerland: species versus community approach.Crossref | GoogleScholarGoogle Scholar |