Linking complex forest fuel structure and fire behaviour at fine scales
E. Louise Loudermilk A I , Joseph J. O’Brien B , Robert J. Mitchell C , Wendell P. CropperA School of Natural Resources and Environment, University of Florida, PO Box 110410, Gainesville, FL 32611, USA.
B USDA Forest Service, Center for Forest Disturbance Science, Forestry Sciences Laboratory, 320 Green Street, Athens, GA 30602, USA.
C Joseph W. Jones Ecological Research Center at Ichauway, 3988 Jones Center Drive, Newton, GA 39870, USA.
D School of Forest Resources and Conservation, University of Florida, PO Box 110410, Gainesville, FL 32611, USA.
E Eglin Air Force Base, Natural Resource Branch, 107 Highway 85 North, Niceville, FL 32578, USA.
F Soil and Water Science Department, University of Florida, PO Box 110290, Gainesville, FL 32611, USA.
G Department of Statistics, University of South Carolina, 1523 Greene Street, Columbia, SC 29208, USA.
H Geosensing Engineering and Mapping Center, University of Florida, PO Box 116580, Gainesville, FL 32611, USA.
I Corresponding author. Present address: Department of Environmental Science and Management, Portland State University, PO Box 751, Portland, OR 97207, USA. Email: louise.loudermilk@gmail.com
International Journal of Wildland Fire 21(7) 882-893 https://doi.org/10.1071/WF10116
Submitted: 18 October 2010 Accepted: 21 February 2012 Published: 26 July 2012
Abstract
Improved fire management of savannas and open woodlands requires better understanding of the fundamental connection between fuel heterogeneity, variation in fire behaviour and the influence of fire variation on vegetation feedbacks. In this study, we introduce a novel approach to predicting fire behaviour at the submetre scale, including measurements of forest understorey fuels using ground-based LIDAR (light detection and ranging) coupled with infrared thermography for recording precise fire temperatures. We used ensemble classification and regression trees to examine the relationships between fuel characteristics and fire temperature dynamics. Fire behaviour was best predicted by characterising fuelbed heterogeneity and continuity across multiple plots of similar fire intensity, where impacts from plot-to-plot variation in fuel, fire and weather did not overwhelm the effects of fuels. The individual plot-level results revealed the significance of specific fuel types (e.g. bare soil, pine leaf litter) as well as the spatial configuration of fire. This was the first known study to link the importance of fuelbed continuity and the heterogeneity associated with fuel types to fire behaviour at metre to submetre scales and provides the next step in understanding the complex responses of vegetation to fire behaviour.
Additional keywords: fuel heterogeneity, IR imagery, LIDAR, longleaf pine, regression tree, savanna.
References
Bond WJ, Woodward FI, Midgley GF (2005) The global distribution of ecosystems in a world without fire. New Phytologist 165, 525–538.| The global distribution of ecosystems in a world without fire.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD2M%2Fpt1OktQ%3D%3D&md5=bd3d76d84f18b8e5e453fde42e8e2efcCAS |
Breiman L, Friedman JH, Olshen RA, Stone CJ (1984) ‘Classification and Regression Trees.’ (Wadsworth, Inc.: Belmont, CA)
Brown JK (1974) Handbook for inventorying downed woody material. USDA Forest Service, Intermountain Research Station, Report GTR-INT-16. (Ogden, UT)
Brown JK (1981) Bulk densities of non-uniform surface fuels and their application to fire modeling. Forest Science 27, 667–683.
De’ath G, Fabricius KE (2000) Classification and regression trees: a powerful yet simple technique for ecological data analysis. Ecology 81, 3178–3192.
| Classification and regression trees: a powerful yet simple technique for ecological data analysis.Crossref | GoogleScholarGoogle Scholar |
DeBano LF, Neary DG, Ffolliott PF (1998) ‘Fire Effects on Ecosystems.’ (Wiley: New York)
Dupuy J, Vachet P, Maréchal J, Meléndez J, de Castro AJ (2007) Thermal infrared emission–transmission measurements in flames from a cylindrical forest fuel burner. International Journal of Wildland Fire 16, 324–340.
| Thermal infrared emission–transmission measurements in flames from a cylindrical forest fuel burner.Crossref | GoogleScholarGoogle Scholar |
Grace J, José JS, Meir P, Miranda HS, Montes RA (2006) Productivity and carbon fluxes of tropical savannas. Journal of Biogeography 33, 387–400.
| Productivity and carbon fluxes of tropical savannas.Crossref | GoogleScholarGoogle Scholar |
Grunwald S, Daroub SH, Lang TA, Diaz OA (2009) Tree-based modeling of complex interactions of phosphorus loadings and environmental factors. The Science of the Total Environment 407, 3772–3783.
| Tree-based modeling of complex interactions of phosphorus loadings and environmental factors.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXltVamu74%3D&md5=7e692ef1b94e544a3132f6ca0b7696b2CAS |
Hall SA, Burke IC, Box DO, Kaufmann MR, Stoker JM (2005) Estimating stand structure using discrete-return LIDAR: an example from low-density, fire-prone ponderosa pine forests. Forest Ecology and Management 208, 189–209.
| Estimating stand structure using discrete-return LIDAR: an example from low-density, fire-prone ponderosa pine forests.Crossref | GoogleScholarGoogle Scholar |
Hendricks JJ, Wilson CA, Boring LR (2002) Foliar litter position and decomposition in a fire-maintained longleaf pine–wiregrass ecosystem. Canadian Journal of Forest Research 32, 928–941.
| Foliar litter position and decomposition in a fire-maintained longleaf pine–wiregrass ecosystem.Crossref | GoogleScholarGoogle Scholar |
Hiers JK, O’Brien JJ, Will RE, Mitchell RJ (2007) Forest floor depth mediates understory vigor in xeric Pinus palustris ecosystems. Ecological Applications 17, 806–814.
| Forest floor depth mediates understory vigor in xeric Pinus palustris ecosystems.Crossref | GoogleScholarGoogle Scholar |
Hiers JK, O’Brien JJ, Mitchell RJ, Grego JM, Loudermilk EL (2009) The wildland fuel cell concept: an approach to characterize fine-scale variation in fuels and fire in frequently burned longleaf pine forests. International Journal of Wildland Fire 18, 315–325.
| The wildland fuel cell concept: an approach to characterize fine-scale variation in fuels and fire in frequently burned longleaf pine forests.Crossref | GoogleScholarGoogle Scholar |
Hopkinson C, Chasmer L, Colin Y-P, Treitz P (2004) Assessing forest metrics with a ground-based scanning LIDAR. Canadian Journal of Forest Research 34, 573–583.
| Assessing forest metrics with a ground-based scanning LIDAR.Crossref | GoogleScholarGoogle Scholar |
Kennard DK, Outcalt KW, Jones D, O’Brien JJ (2005) Comparing techniques for estimating flame temperature of prescribed fires. Fire Ecology 1, 75–84.
| Comparing techniques for estimating flame temperature of prescribed fires.Crossref | GoogleScholarGoogle Scholar |
Lefsky MA, Cohen WB, Acker SA, Parker GG, Spies TA, Harding D (1999) LIDAR remote sensing of the canopy structure and biophysical properties of Douglas-fir western hemlock forests. Remote Sensing of Environment 70, 339–361.
| LIDAR remote sensing of the canopy structure and biophysical properties of Douglas-fir western hemlock forests.Crossref | GoogleScholarGoogle Scholar |
Lewis RO (1992) ‘Independent Verification and Validation: a Life-cycle Engineering Process for Quality Software.’ (Wiley: New York)
Loudermilk EL (2010) Linking plant demography, forest fuels, and fire in longleaf pine (Pinus palustris) savannas using LIDAR remote sensing and simulation modeling. PhD thesis, University of Florida, Gainesville.
Loudermilk EL, Hiers JK, O’Brien JJ, Mitchell RJ, Singhania A, Fernandez JC, Cropper WP, Slatton KC (2009) Ground-based LIDAR: a novel approach to quantify fine-scale fuelbed characteristics. International Journal of Wildland Fire 18, 676–685.
| Ground-based LIDAR: a novel approach to quantify fine-scale fuelbed characteristics.Crossref | GoogleScholarGoogle Scholar |
Loudermilk EL, Cropper WP, Mitchell RJ, Lee H (2011) Longleaf pine (Pinus palustris) and hardwood dynamics in a fire-maintained ecosystem: a simulation approach. Ecological Modelling 222, 2733–2750.
| Longleaf pine (Pinus palustris) and hardwood dynamics in a fire-maintained ecosystem: a simulation approach.Crossref | GoogleScholarGoogle Scholar |
McNab WH, Avers PE (1994) ‘Ecological subregions of the United States: section descriptions.’ (USDA Forest Service: Washington, DC)
McPherson GR (1997) ‘Ecology and Management of North American Savannas.’ (University of Arizona Press: Tucson, AZ)
Mitchell RJ, Hiers JK, O’Brien JJ, Jack SB, Engstrom RT (2006) Silviculture that sustains: the nexus between silviculture, frequent prescribed fire, and conservation of biodiversity in longleaf pine forests of the south-eastern United States. Canadian Journal of Forest Research 36, 2724–2736.
| Silviculture that sustains: the nexus between silviculture, frequent prescribed fire, and conservation of biodiversity in longleaf pine forests of the south-eastern United States.Crossref | GoogleScholarGoogle Scholar |
Mitchell RJ, Hiers JK, O’Brien J, Starr G (2009) Ecological forestry in the south-east: understanding the ecology of fuels. Journal of Forestry 107, 391–397.
Ottmar RD, Sandberg DV, Riccardi CL, Prichard SJ (2007) An overview of the Fuel Characteristic Classification System – quantifying, classifying, and creating fuelbeds for resource planning. Canadian Journal of Forest Research 37, 2383–2393.
| An overview of the Fuel Characteristic Classification System – quantifying, classifying, and creating fuelbeds for resource planning.Crossref | GoogleScholarGoogle Scholar |
Pecot SD, Mitchell RJ, Palik BJ, Moser EB, Hiers JÂK (2007) Competitive responses of seedlings and understory plants in longleaf pine woodlands: separating canopy influences above and below ground. Canadian Journal of Forest Research 37, 634–648.
| Competitive responses of seedlings and understory plants in longleaf pine woodlands: separating canopy influences above and below ground.Crossref | GoogleScholarGoogle Scholar |
Popescu SC, Wynne RH, Scrivani JA (2004) Fusion of small-footprint LIDAR and multispectral data to estimate plot-level volume and biomass in deciduous and pine forests in Virginia, USA. Forest Science 50, 551–565.
Power M (1993) The predictive validation of ecological and environmental models. Ecological Modelling 68, 33–50.
| The predictive validation of ecological and environmental models.Crossref | GoogleScholarGoogle Scholar |
Prasad A, Iverson L, Liaw A (2006) Newer classification and regression tree techniques: bagging and random forests for ecological prediction. Ecosystems 9, 181–199.
| Newer classification and regression tree techniques: bagging and random forests for ecological prediction.Crossref | GoogleScholarGoogle Scholar |
Riaño D, Meier E, Allgower B, Chuvieco E, Ustin SL (2003) Modeling airborne laser scanning data for the spatial generation of critical forest parameters in fire behavior modeling. Remote Sensing of Environment 86, 177–186.
| Modeling airborne laser scanning data for the spatial generation of critical forest parameters in fire behavior modeling.Crossref | GoogleScholarGoogle Scholar |
Riaño D, Valladares F, Condes S, Chuvieco E (2004) Estimation of leaf area index and covered ground from airborne laser scanner (LIDAR) in two contrasting forests. Remote Sensing of Environment 124, 269–275.
Rykiel EJ (1996) Testing ecological models: the meaning of validation. Ecological Modelling 90, 229–244.
| Testing ecological models: the meaning of validation.Crossref | GoogleScholarGoogle Scholar |
Sargent RG (2005) Verification and validation of simulation models. In ‘Proceedings of the 37th Conference on Winter Simulation’, 4–7 December 2005, Orlando, FL. pp. 130–143. (Winter Simulation Conference: Orlando, FL)
Seni G, Elder JF (2010) Ensemble methods in data mining: improving accuracy through combining predictions. In ‘Synthesis Lectures on Data Mining and Knowledge Discovery. Vol. 2.’ (Eds J Han, L Getoor, W Wang, J Gehrke, R Grossman) pp. 1–126. (Morgan and Claypool Publishers: San Rafael, CA)
Smith WB, Miles PD, Perry CH, Pugh SA (2009) ‘Forest Resources of the United States, 2007.’ (USDA Forest Service: Washington, DC)
Su JG, Bork EW (2007) Characterization of diverse plant communities in Aspen Parkland rangeland using LiDAR data. Applied Vegetation Science 10, 407–416.
| Characterization of diverse plant communities in Aspen Parkland rangeland using LiDAR data.Crossref | GoogleScholarGoogle Scholar |
Vasques GM, Grunwald S, Sickman JO (2009) Modeling of soil organic carbon fractions using visible–near-infrared spectroscopy. Soil Science Society of America Journal 73, 176–184.
| Modeling of soil organic carbon fractions using visible–near-infrared spectroscopy.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXitVarsL0%3D&md5=491f599ba8393aac4fab8964558d4c39CAS |
Wade DD, Lunsford JD, Dixon MJ, Mobley HE (1989) A guide for prescribed fire in southern forests. USDA Forest Service, Southern Region Technical Publication TP-R8–11. (Atlanta, GA)
Whelan RJ (1995) ‘The Ecology of Fire.’ (Cambridge University Press: Cambridge, UK)
Wing MG, Eklund A, Sessions J (2010) Applying LiDAR technology for tree measurements in burned landscapes. International Journal of Wildland Fire 19, 104–114.
| Applying LiDAR technology for tree measurements in burned landscapes.Crossref | GoogleScholarGoogle Scholar |