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Charcoal Production from Agricultural Burning in Central Panama and its Deposition in the Sediments of the Gulf of Panama

Published online by Cambridge University Press:  24 August 2009

Daniel O. Suman
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Extract

Widespread agricultural burning during the dry season in the Pacific watershed of Panama is an important ecological phenomenon. During that time over 10% of the land surface (woodlands and savannas) is burned annually, with the resulting production of large amounts of charcoal. The major portion of the charcoal remains on land, but 5% is mobilized by river runoff and winds to the sediments of the Gulf of Panama.

The aeolian transport of particulate charcoal by the north-easterly Trade Winds has been monitored by dry-deposition and aerosol paniculate collectors. During the burning-season, atmospheric charcoal concentrations in rural Panama can be similar to urban concentrations in North America or Europe. More than 60% of the charcoal aerosol mass was carried as fine particles (< 2 urn diameter), suggesting that long-range transport is possible.

Dry-deposition fluxes, which are positively correlated with the areal extent of land that is burned, are more than an order of magnitude less than the charcoal fluxes to the uppermost near-shore sedimentary deposits in the Gulf of Panama. This implies that aeolian transport is not the principal mechanism of charcoal mobilization to these sediments. The extremely high runoff per unit area in the Gulf of Panama watershed is probably responsible for the predominance of continental runoff as the charcoal transport mechanism in the region.

Being relatively indestructible, charcoal can also be used as a tracer for past burning activities. Sediment box-cores have been recovered from the Gulf of Panama, and Pb-210 geochronologies were utilized to determine sedimentation rates. The charcoal particles were isolated by chemical methods and their fluxes, size-distributions, and morphologies, were analysed. The relative uniformity of these measurements in the marine sediment geochronologies indicates stability of burning patterns in central Panama during the last two centuries.

Type
Main Papers
Information
Environmental Conservation , Volume 13 , Issue 1 , Spring 1986 , pp. 51 - 60
Copyright
Copyright © Foundation for Environmental Conservation 1986

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References

Adams, J.A.S., Mantovani, M.S.M. & Lundell, L.L. (1977). Wood versus fossil fuel as a source of excess carbon dioxide in the atmosphere: a preliminary report. Science, 196, pp. 54–6, illustr.CrossRefGoogle ScholarPubMed
Ajtay, G.L., Ketner, P. & Duvigneaud, P. (1979). Terrestrial primary production and phytomass. Pp. 129–82 in The Global Carbon Cycle (Eds Bolin, B., Degens, E.T., Kempe, S. & Ketner, P.). John Wiley & Sons, Chichester, England, UK: xxx v + 491 pp., illustr.Google Scholar
Allen, T. (1974). Particle Size Measurement. Chapman & Hall, London, England, UK: xviii + 454 pp., illustr.Google Scholar
Bennett, C.F. (1968). Human Influences on the Zoogeography of Panama. University of California Press, Berkeley, California, USA: vii + 112 pp., illustr., maps.Google Scholar
Bramryd, T. (1979). The effects of man on the biogeochemical cycle of carbon in terrestrial ecosystems. Pp. 183218 in The Global Carbon Cycle (Eds Bolin, B., Degens, E.T., Kempe, S. & Ketner, P.). John Wiley & Sons, Chichester, England, UK: xxxv + 491 pp., illustr.Google Scholar
Forsbergh, E.D. (1969). On the climatology, oceanography, and fisheries of the Panama Bight. Bulletin of the Inter-American Tropical Tuna Commission, 14, pp. 49110, illustr.Google Scholar
Fuson, R.H. (1958). The Savanna of Central Panama: A Study in Cultural Geography. Ph.D. thesis, Louisiana State University, Baton Rouge, Louisiana, USA: 487 pp., illustr. (mimeogr.).Google Scholar
Greenberg, J.P., Zimmerman, P.R., Heidt, L. & Pollack, W. (1984). Hydrocarbon and carbon monoxide emissions from biomass burning in Brazil. J. Geophys. Res., 89 (D1), pp. 1350–4, illustr.CrossRefGoogle Scholar
Griffin, J.J. & Goldberg, E.D. (1975). The fluxes of elemental carbon in coastal marine sediments. Limnology and Oceanography, 20, pp. 456–63, illustr.CrossRefGoogle Scholar
Griffin, J.J. & Goldberg, E.D. (1981). Sphericity as a characteristic of solids from fossil fuel burning in a Lake Michigan sediment. Geochim. et Cosmochim. Acta, 45, pp. 763–9, illustr.CrossRefGoogle Scholar
Griffin, J.J. & Goldberg, E.D. (1983). Impact of fossil fuel combustion on sediments of Lake Michigan: a reprise. Environmental Science and Technology, 17, pp. 244–5, illustr.CrossRefGoogle Scholar
Guzman, L.E. (1956). Farming and Farmlands in Panama. Department of Geography Research Paper, No. 44, University of Chicago, Chicago, Illinois, USA: x + 137 pp., illustr., maps.Google Scholar
Hampicke, U. (1979). Net transfer of carbon between the land biota and the atmosphere induced by man. Pp. 219–36 in The Global Carbon Cycle (Eds Bolin, B., Degens, E.T., Kempe, S. & Ketner, P.). John Wiley & Sons, Chichester, England, UK: xxxv + 491 pp., illustr.Google Scholar
Hopkins, B. (1965). Observations on savanna burning in the Olokemeji Forest Reserve, Nigeria. J. Appl. Ecology, 2, pp. 367–81, illustr.CrossRefGoogle Scholar
Instituto Geográfico Nacional (1975). Atlas Nacional de Panamá. Ministry of Public Works, National Geographic Institute, Panamá: xiv + 103 pp., illustr., maps.Google Scholar
Jutze, G.A. & Foster, K.E. (1967). Recommended standard method for atmospheric sampling of fine particulate matter by filter media—high volume sample. J. Air Poll. Control Assn., 17, pp. 1725, illustr.CrossRefGoogle Scholar
Koide, M. & Bruland, K.W. (1975). The electrodeposition and determination of radium by isotopic dilution in seawater and in sediments simultaneously with other natural radionuclides. Anal. Chim. Acta, 75, pp. 119, illustr.CrossRefGoogle Scholar
Koide, M., Bruland, K.W. & Goldberg, E.D. (1973). Th-228/Th-232 and Pb-210 geochronologies in marine and lake sediments. Geochim. et Cosmochim. Acta, 37, pp. 1171–88, illustr.CrossRefGoogle Scholar
Krumbein, W.C. & Pettijohn, F.J. (1938). Manual of Sedimentary Petrography. D. Appleton-Century, New York, NY, USA: xiv+ 549 pp., illustr.Google Scholar
Lewis, C. & Macias, E. (1980). Composition of size-fractionated aerosol in Charleston, West Virginia. Atmospheric Environment, 14, pp. 185–94, illustr.CrossRefGoogle Scholar
Malissa, H. (1979). Some analytical approaches to the chemical characterization of carbonaceous particles. Pp. 39 in Carbonaceous Particles in the Atmosphere (Ed. Novakov, T.). Lawrence Berkeley Laboratory, Berkeley, California, USA: ix + 283 pp., illustr.Google Scholar
Minnich, R.A. (1983). Fire mosaics in southern California and northern Baja California. Science, 219, pp. 1287–94, illustr.CrossRefGoogle ScholarPubMed
Muller, J. (1959). Palynology of recent Orinoco Delta and shelf sediments: reports of the Orinoco Shelf Expedition, Volume 5. Micropaleontology, 5, pp. 132, illustr.CrossRefGoogle Scholar
Myers, N. (1981). The hamburger connection: how Central America's forests become North America's hamburgers. Ambio, 10, pp. 38, illustr.Google Scholar
Orr, C. & Keng, E.Y.H. (1976). Sampling and particle size measurement. Pp. 93117 in Handbook on Aerosols (Ed. Dennis, R.). US Office of Scientific Research and Development, National Defense Research Committee, Washington, DC, USA: v+ 142 pp., illustr.Google Scholar
Prospero, J.M. (1981). Eolian transport to the world ocean. Pp. 801–74 in The Oceanic Lithosphere (The Sea, Vol. 7) (Ed. Emiliani, C.). John Wiley & Sons, New York, NY, USA: xii + 1738 pp., illustr., maps.Google Scholar
Root, B.D. (1976). An estimate of annual global atmospheric pollutant emissions from grassland fires and agricultural burning in the tropics. Professional Geographer, 28, pp. 349–52.CrossRefGoogle Scholar
Rosen, H., Hansen, A.D.A., Dod, R.L., Gundel, L.A. & Novakov, T. (1982). Graphitic carbon in urban environment and the Arctic. Pp. 273–94 in Paniculate Carbon—Atmospheric Life Cycle (Eds Wolff, G.T. & Klimisch, R.L.). Plenum Press, New York, NY, USA: x + 411 pp., illustr.Google Scholar
Sauer, C.O. (1969). The Early Spanish Main. University of California Press, Berkeley, California, USA: xii + 306 pp., illustr., maps.Google Scholar
Schwerdtfeger, W. (1976). Climates of Central and South America. (World Survey of Climatology, Vol. 12.) Elsevier Scientific Scientific Publishing Company, Amsterdam, Netherlands: xii + 532 pp., illustr.Google Scholar
Seiler, W. & Crutzen, P. (1980). Estimates of gross and net fluxes of carbon between the biosphere and the atmosphere from biomass burning. Climatic Change, 2, pp. 207–47.CrossRefGoogle Scholar
Smith, D.M. & Griffin, J.J. (1975). Spectrometric method for the quantitative determination of elemental carbon. Anal. Chem., 47, pp. 233–8, illustr.CrossRefGoogle Scholar
Suárez, O. Jaen (1979). La Población del Istmo de Panamá del Siglo XVI al Sigh XX. Impresora de la Naci´n, Panamá: 603 pp., illustr., maps.Google Scholar
Suman, D. (1983). Agricultural Burning in Panama and Central America: Burning Parameters and the Coastal Sedimentary Record. Ph.D. thesis, University of California, San Diego, California, USA: 172 pp., illustr. (mimeogr. and microfilm).Google Scholar
Turco, R.P., Toon, O.B., Whitten, R.C., Pollack, J.B. & Hamill, P. (1982). The Global Cycle of Paniculate Elemental Carbon: A Theoretical Assessment. Paper read at the 4th International Conference on Precipitation Scavenging, Dry Deposition, and Resuspension, Santa Monica, California, USA: [not available for checking].Google Scholar
Wafer, L. (1704). A New Voyage and Description of the Isthmus of America. James Knapton, London, England, UK: 8 + 283 pp. + unnumbered pages and illustrations.Google Scholar
Weiss, R.E. & Waggoner, A.P. (1982). Optical measurements of airborne soot in urban, rural and remote locations. Pp. 317–42 in Paniculate Carbon - Atmospheric Life Cycle (Eds Wolff, G.T. & Klimisch, R.L.). Plenum Press, New York, NY, USA: x + 411 pp., illustr.Google Scholar
Whittaker, R.H. (1975). Communities and Ecosystems. Macmillan Press, New York, NY, USA: xviii + 385 pp., illustr.Google Scholar
Wolff, G.T., Groblicki, P.J., Cadle, S.H. & Countless, R.J. (1982). Paniculate carbon at various locations in the United States. Pp. 297315 in Paniculate Carbon—Atmospheric Life Cycle (Eds Wolff, G.T. & Klimisch, R.L.). Plenum Press, New York, NY, USA: x + 411 pp., illustr.Google Scholar
Woodwell, G.M. (1978). The carbon dioxide question. Scientific American, 238, pp. 3443, illustr.CrossRefGoogle Scholar
Woodwell, G.M., Hobbie, J.E., Houghton, R.A., Melillo, J.M., Moore, B., Peterson, B.J. & Shaver, G.R. (1983). Global deforestation: contribution to atmospheric carbon dioxide. Science, 222, pp. 1081–6, illustr.CrossRefGoogle ScholarPubMed