1 Spatial Modelling of the Terrestrial Environment - Georeferencial

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Fireline Intensity and Biomass Consumption in Wildland Fires 193 for small experimental fires, and there is a clear need for further work in this area now methods to accurately assess the radiative component are at hand. If proved valid and of sufficient accuracy and precision, the new remotely derived estimates of heat generation, fireline intensity and vegetation combustion will be of significant value in the estimation of emissions’ products and also the study of how wildfires propagate through the spatial environment. As such, research continues at a variety of spatial scales on improving the understanding of these concepts, on the relationship between them, and on the accuracy with which they can be estimated using these new EO approaches. Acknowledgements M. Wooster is supported by the NERC Earth Observation Science Initiative and is grateful to the NERC Equipment Pool for Field Spectroscopy for much advice and for the loan of the GER3700 field spectrometer. MODIS and ASTER data were obtained via the NASA Goddard Space Flight Center (GSFC) and EROS Data Centre Distributed Active Archive Centres (DAACs). Louis Giglio provided useful advice regarding use of the MODIS Fire Products. Radiosonde data were kindly provided by the Australian Bureau of Meteorology. References Albini, F.A., 1976, Estimating Wildland Fire Behaviour and Effects, USDA Forest Service, General Technical Report, GTR-INT 30. Albini, F.A., 1980, Thermochemical Properties of Flame Gases for Fine Wildland Fuels, USDA Forest Service, General Research Paper, INT 243. Albini, F.A., 1993, Dynamics and modelling of vegetation fires: observations, in P.J. Crutzen and J.G. Goldammer (eds), Fire in the Environment: The Ecological, Atmospheric and Climatic Importance of Vegetation Fires (New York: John Wiley and Sons), 39–53. Alexander, M.E., 1982, Calculating and interpreting forest fire intensities, Canadian Journal of Botany, 60, 349–357. Anders, E., Wolbach, W.S. and Gilmour, I., 1991, Major wildland fires at the Cretaceous-Tertiary boundary, in J.S. Levine (ed.), Global Biomass Burning (Cambridge, MA: MIT Press), 485–492. Anderson, H.E., 1969, Heat Transfer and Fire Spread, USDA Forest Research Paper, INT-69. Andreae, M.O. and Merlet, P., 2001, Emission of trace gases and aerosols from biomass burning, Global Biogeochemical Cycles, 15, 955–966. Barbosa, P., Stroppiana, D., Gregoir, J. and Pereira, J., 1999, An assessment of vegetation fire activity in Africa (1981–1991): burned areas, burned biomass and atmospheric emissions, Global Biogeochemical Cycles, 13, 933–950. Beniston, M., Innes, J. and Verstraete, M., 2000, Biomass burning and its inter-relationships with the climate system, in Advances in Global Change Research, Vol. 3 (Dordrecht: Kluwer). Bond, W.J. and van Wilgen, B.W., 1996, Fire and Plants (London: Chapman and Hall). Bradstock, R.A., Gill, A.M., Kenny, B.J. and Scott, J., 1998, Bushfire risk at the urban interface estimated from historical weather records: consequences for the use of prescribed fire in the Sydney region of south-eastern Australia, Journal of Environmental Management, 52, 259–271. Brain, C.K. and Sillen, A., 1988, Evidence from the Swartkans cave for the earliest use of fire by hominids, Nature, 336, 464–466. Briess, K., Jahn, H., Lorenz, E., Oertel, D., Skrbek, W. and Zhukov, B., 2003, Fire recognition potential of the Bi-spectral InfraRed Detection (BIRD) satellite, International Journal of Remote Sensing, 24, 865–872. Brown, N., 1998, Out of control: fires and forestry in Indonesia, Trends in Ecology and Evolution, 13, 41.
194 Spatial Modelling of the Terrestrial Environment Budd, G.M., Brotherhood, J.R., Hendrie, A.L., Jeffery, S.E., Beasley, F.A., Costin, B.P., Zhien, W., Baker, M.M., Cheney, N.P. and Dawson M.P., 1997, Project Aquarius 4. Experimental bushfires, suppression procedures, and measurements, International Journal of Wildland Fire, 7, 99–104. Burgan, R.E. and Rothermel, R.C., 1984, BEHAVE – Fire Behaviour Prediction and Fuel Modeling System: Fuel Subsystem, USDA Forest Service General Technical Report, INT-238. Byram, G.M., 1959, Combustion of forest fuels, in K.P. Davis (ed.), Forest Fires: Control and Use (New York: McGraw-Hill), 65–89. Caldararo, N., 2002, Human ecological intervention and the role of forest fires in human ecology, Science of the Total Environment, 292, 141–165. Chandler, C.C., Cheney, P., Thomas, P., Trabaud, L. and Williams, D., 1983, Fire in Forestry Volume 1: Forest Fire Behaviour and Effects (New York: John Wiley and Sons). Cheney, N.P., 1990, Quantifying bushfires, Mathematical and Computer Modelling, 13, 9–15. Chou, M.D., Chan, P.K. and Wang, M.H., 2002, Aerosol radiative forcing derived from SeaWiFSretrieved aerosol optical properties, Journal of the Atmospheric Science, 59, 748–757. Cope, M.J. and Chaloner, W.G., 1985, Wildfire: an interaction of biological and physical processes, in B.H. Tiffney (eds), Geological Factors and the Evolution of Plants (London: Yale University Press), 257–277. Enright, N.J., Goldblum, D., Ata, P. and Ashton, D.H., 1997, The independent effects of heat, smoke and ash on emergence of seedlings from the soil seed bank of a healthy Eucalptus woodland in Grampians (Gariwerd) National Park, western Victoria, Australian Journal of Ecology, 22,81–88. ERSDAC, 2001, ASTER Users Guide Part 1, Earth Remote Sensing Data Analysis Centre, Tokyo. Ferguson, S., Sandberg, D. and Ottmar, R., 2000, Modelling the effect of landuse changes on global biomass emissions, in J.L. Innes, M. Beniston and M.M. Verstraete (eds), Biomass Burning and its Inter-Relationship with the Climate System (Dordrecht: Kluwer), 33–50. Fuller, M., 1991, Forest Fires: An Introduction to Wildland Fire Behaviour, Management, Fire Fighting and Prevention (New York: John Wiley and Sons). Goode, J., Yokelson, R., Ward, D., Susott, R., Babbitt, R., Davies, M. and Hao, W., 2000, Measurements of excess O 3 ,CO 2 , CO, CH 4 ,C 2 H 4 ,C 2 H 2 , HCN, NO, NH 3 , HCOOH, CH 3 COOH, HCHO, and CH 3 OH in 1997 Alaskan biomass burning plumes by airborne Fourier transform infrared spectroscopy (AFTIR), Journal of Geophysical Research, 105, 22147–22166. Hufford, G.L., Kelley, H.L., Moore, R.K. and Cotterman, J.S. 2000, Detection and growth of an Alaskan forest fire using GOES-9 3.9 micron imagery, International Journal of Wildland Fire, 9, 126–136. Johansen, M.P., Hakonson, T.E. and Breshears, D.D., 2001, Post-fire runoff and erosion from rainfall simulation: contrasting forests with shrublands and grasslands, Hydrological Processes, 15, 2953– 2965. Kaufman, Y.J., Kleidman, R.G. and King, M.D., 1998a, SCAR-B fires in the tropics: properties and remote sensing from EOS-MODIS, Journal of Geophysical Research, 103, 31955–31968. Kaufman, Y.J., Tanre, D. and Boucher, O., 2002, A satellite view of aerosols in the climate system, Nature, 419, 215–223. Kaufman, Y.J., Tucker, C.J. and Fung I., 1990, Remote sensing of biomass burning in the tropics, Journal of Geophysical Research, 95, 9927–9939. Kaufman, Y.J., Justice, C.O., Flynn, L.P., Kendall, J.D., Prins, E.M., Giglio, L., Ward, D.E., Menzel P. and Setzer, A.W., 1998b, Potential global fire monitoring from EOS-MODIS, Journal of Geophysical Research, 103, 32215–32238. Kaufman, Y., Remer, L., Ottmar, R., Ward, D., Rong-R, L., Kleidman, R., Fraser, R., Flynn, L., McDougal, D. and Shelton, G., 1996, Relationship between remotely sensed fire intensity and rate of emission of smoke: SCAR-C experiment, in J. Levine (ed.), Global Biomass Burning (Cambridge, MA: MIT Press), 685–696. Keith, D.A., 1996, Fire-driven extinction of plant populations: a synthesis of theory and review of evidence from Australian vegetation, Proceedings of the Linnean Society of New South Wales, 116, 37–78. Keller, F., Lischke, H., Mathis, T., Mohl, A., Wick, L., Ammann, B. and Kienast, F., 2002, Effects of climate, fire, and humans on forest dynamics: forest simulations compared to the palaeological record, Ecological Modelling, 152, 109–127.
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Spatial Modelling of the Terrestria
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Copyright C○ 2004 John Wiley & So
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Contents List of Contributors Prefa
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Contributors Jonathan L. Bamber Sch
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List of Contributors xi George Perr
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xiv Preface in theory and applicati
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2 Spatial Modelling of the Terrestr
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Editorial: Spatial Modelling in Hyd
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Editorial: Spatial Modelling in Hyd
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2 Modelling Ice Sheet Dynamics with
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Modelling Ice Sheet Dynamics by Sat
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36 Spatial Modelling of the Terrest
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4 Using Coupled Land Surface and Mi
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Coupled Land Surface and Microwave
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100 Spatial Modelling of the Terres
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Editorial: Terrestrial Sediment and
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Editorial: Terrestrial Sediment and
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6 Remotely Sensed Topographic Data
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Remotely Sensed Topographic Data fo
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7 Modelling Wind Erosion and Dust E
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Modelling Wind Erosion and Dust Emi
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Modelling Wind Erosion and Dust Emi
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Page 164 and 165: 8 Near Real-Time Modelling of Regio
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Page 194 and 195: Figure 9.4 The upper row shows EOS
Page 204 and 205: PART III SPATIAL MODELLING OF URBAN
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Page 232 and 233: 11 Modelling the Impact of Traffic
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Page 248 and 249: PART IV CURRENT CHALLENGES AND FUTU
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268 Index Bi-spectral InfraRed Dete
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270 Index floodplain maps, UK 92 fl
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272 Index Long-Term Ecological Rese
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274 Index snow depth measurement ne
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276 Index urban land use in remotel
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