Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-25T10:23:16.789Z Has data issue: false hasContentIssue false

Particle Motion and the Theory of Charcoal Analysis: Source Area, Transport, Deposition, and Sampling

Published online by Cambridge University Press:  20 January 2017

James S. Clark*
Affiliation:
Department of Ecology and Behavioral Biology, 318 Church St. S.E., 105 Zoology and The Limnological Research Center, 220 Pillsbury Hall, University of Minnesota, Minneapolis, Minnesota 55445

Abstract

Principles from particle-motion physics were applied to recurring problems of the interpretation of stratigraphic charcoal data: (1) fires within catchments of lakes often produce no record in fossil-charcoal curves and (2) periods characterized by no local fire (e.g., 20th-century fire suppression) often display as much charcoal as times when local fire was frequent. Quantitative theory on source area, transport, deposition, and sampling of charcoal shows the relationship between particle sizes counted by alternative methods of charcoal analysis (pollen slides for particles 5–80 μm in diameter, petrographic thin sections for particles 50–10,000 μm diameter) and charcoal diagrams. The relationship between diameter and critical and deposition velocities results in fundamental aerodynamic differences between the sizes of particles quantified by the two methods. Charcoal recorded on pollen slides is of a size that is difficult to lift, but once entrained it remains in suspension. Thin-section charcoal is lifted at relatively low wind velocities, but it is not suspended at normal surface wind speeds. Thermal buoyancy during fire lofts charcoal above the forest canopy, depending on particle size and wind speed. Pollen-slide charcoal sizes are underrepresented near the fire, because they remain in suspension and are preferentially exported from the burn area. Thin-section charcoal is convected to lower heights on average and is deposited nearby. Following fire, thin-section charcoal is redistributed locally by wind and thus may enter lakes. Because of cohesive forces and aerodynamics, more pollen-slide charcoal remains on the ground, and less enters lakes. Source areas for pollen-slide charcoal are subcontinental to global, and diagrams of pollen-slide charcoal are biased toward nonlocal charcoal. They can be used to interpret importance of fire for broad spatial and temporal scales. Thin-section charcoal represents, the catchment fire regime. Simulation models that generate charcoal during fire, mix sediments, and then sample at specified intervals indicate that (1) in the absence of sediment mixing the pollen-slide method should consistently resolve individual fires that occur with an expectation of >30–50 yr, (2) unless samples are continuous, neither method will produce useful estimates of fire frequency, and (3) even a modest amount of sediment mixing will obscure the signal.

Type
Research Article
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Agee, J.K., (1981). Initial Effects of Prescribed Fire in a Climax Pinus Contorta Forest: Crater Lake National Park. National Park Service Cooperative Studies Unit, University of Washington CPSU/UW, 81-84.Google Scholar
Anderson, R.S., Davis, R.B., Miller, N.G., Stuckenrath, R., (1986). History of late- and post-glacial vegetation and disturbance around Upper South Branch Pond, northern Maine. Canadian Journal of Botany. 64, 1977-1986.Google Scholar
Backman, A.E., (1984). 1000-Yr Record of Fire-Vegetation Interactions in the Northeastern United States: A Comparison of Coastal and Inland Regions. Masters thesis. University of Massachusetts.Google Scholar
Bagnold, R.A., (1941). The Physics of Blown Sand and Desert Dunes. Methuen, London.Google Scholar
Bonny, A.P., (1976). Recruitment of pollen to the seston and sediment of some Lake District Lakes. Journal of Ecology. 64, 859-888.Google Scholar
Bradbury, J.P., (1986). Effects of forest fire and other disturbances on wilderness lakes in northeastern Minnesota. II. Paleolimnology. Archiv Für Hydrobiologie. 106, 203-217.CrossRefGoogle Scholar
Chamberlain, A.C., (1955). Aspects of Travel and Deposition of Aerosol and Vapour Clouds. 1-35, Atomic Energy Research Establishment Report HP/R 1261.Google Scholar
Chamberlain, A.C., The movement of particles in plant communities. Monteith, J.L., (1975). Vegetation and the Atmosphere. Academic Press, New York, 155-204.Google Scholar
Chandler, C., Cheney, P., Thomas, P., Trabaud, L., Williams, D., (1983). Fire in Forestry. Vol. I Wiley, New York, “Forest Fire Behavior and Effects.”.Google Scholar
Clark, J.S., 1988a. Stratigraphic charcoal analysis on petrographic thin sections: Application to fire history in northwestern Minnesota. Quaternary Research. 30, 81-91.Google Scholar
Clark, J.S., 1988b. Patterns, causes, and theory of fire occurrence during the last 750 yr in northwestern Minnesota. Ecological Monographs. in press.Google Scholar
Clark, J.S., Merkt, J., Müller, H., (1988). Post Glacial fire, vegetation, and cultural history of the northern Alpine forelands, southwest Germany. Journal of Ecology. in press.Google Scholar
Cwynar, L.C., (1978). Recent history of fire and vegetation from laminated sediment of Greenleaf Lake, Algonquin Park, Ontario. Canadian Journal of Botany. 56, 10-21.CrossRefGoogle Scholar
Davis, M.B., (1972). Redeposition of pollen grains in lake sediments. Limnology and Oceanography. 18, 44-52.CrossRefGoogle Scholar
Foda, M.A., (1983). Dry-fall of fine dust on sea. Journal of Geophysical Research. 88, 6021-6026.CrossRefGoogle Scholar
Foster, D.C., (1976). Lower La Salle Lake, Minnesota: Sedimentation and Recent Fire and Vegetation History. Masters thesis. University of Minnesota.Google Scholar
Foster, D.R., King, G.A., (1986). Vegetation pattern and diversity in S.E. Labrador, Canada: Betula papyrifera (birch) forest development in relation to fire history and physiography. Journal of Ecology. 74, 465-483.CrossRefGoogle Scholar
Frissell, S.S., (1973). The importance of fire as a natural ecological factor in Itasca State Park, Minnesota. Quaternary Research. 3, 397-407.CrossRefGoogle Scholar
Greeley, R., Iversen, J.D., (1985). Wind As a Geological Process on Earth, Mars, Venus, and Titan. Cambridge Univ. Press, Cambridge.CrossRefGoogle Scholar
Green, D.G., (1981). Time series and postglacial forest ecology. Quaternary Research. 15, 265-277.Google Scholar
Gregory, P.H., (1961). The Microbiology of the Atmosphere. Interscience, New York.Google Scholar
Grimm, E.C., (1984). Fire and other factors controlling the Bigs Woods vegetation of Minnesota in the mid-nineteenth century. Ecological Monographs. 54, 291-311.Google Scholar
Heinselman, M.L., (1973). Fire in the virgin forest of the boundary Waters Canoe Area, Minnesota. Quaternary Research. 3, 329-382.Google Scholar
Heinselman, M.L., Fire intensity and frequency as factors in the distribution and structure of northern ecosystems. Mooney, H.A., Bonnicksen, T.M., Christensen, N.L., Lotan, J.E., Reiners, W.A., (1981). Fire Regimes and Ecosystem Properties. United States Forest Service General Technical Report GTR-WO-26. 7-57, Washington, DC.Google Scholar
Kilgore, B.M., Fire in ecosystem distribution and structure: Western forests and scrublands. Mooney, H.A., Bonnickson, T.M., Christensen, N.L., Lotan, J.E., Reiners, W.A., (1981). Fire Regimes and Ecosystem Properties. United States Forest Service General Technical Report WO-26. 58-89, Washington, DC.Google Scholar
Patterson, W.A., (1978). The Effects of Past and Current Land Disturbances on Squaw Lake, Minnesota and Its Watershed. Ph.D. thesis. University of Minnesota.Google Scholar
Patterson, W.A., Edwards, K.J., Maguire, D.J., (1987). Microscopic charcoal as a fossil indicator of fire. Quaternary Science Reviews. 6, 3-23.Google Scholar
Peck, R.M., Pollen budget studies in a small Yorkshire catchment. Birks, H.J.B., West, R.G., (1973). Quaternary Plant Ecology. Blackwell, Oxford, 43-60.Google Scholar
Prentice, I.C., (1985). Pollen representation, source area, and basin size: Toward a unified theory of pollen analysis. Quaternary Research. 23, 76-86.Google Scholar
Romme, W.H., (1982). Fire and landscape diversity in subalpine forests of Yellowstone National Park. Ecological Monographs. 52, 199-221.CrossRefGoogle Scholar
Romme, W.H., Knight, D.H., (1981). Fire frequency and subalpine forest succession along a topographic gradient in Wyoming. Ecology. 62, 319-326.Google Scholar
Rothermal, R.C., (1972). A Mathematical Model for Predicting Fire Spread in Wildland Fuels. USDA Forest Service Intermountain Forest and Range Experiment Station Research Paper INT-115.Google Scholar
Sutton, O.G., (1953). Micrometeorology: A Study of Physical Processes in the Lowest Layer's of the Earth's Atmosphere. McGraw-Hill, New York.Google Scholar
Swain, A.M., (1973). A history of fire and vegetation in northeastern Minnesota as recorded in lake sediment. Quaternary Research. 3, 383-396.CrossRefGoogle Scholar
Swain, A.M., (1978). Environmental changes during the past 2000 years in north-central Wisconsin: Analysis of pollen, charcoal and seeds from varved lake sediments. Quaternary Research. 10, 55-68.Google Scholar
Swain, A.M., (1980). Landscape patterns and forest history in the Boundary Waters Canoe Area, Minnesota: A pollen study from Hug Lake. Ecology. 61, 747-754.Google Scholar
Swain, A.M., (1981). Fire history and vegetation dynamics in northeastern and northcentral United States during the past 2000 years based on pollen and charcoal analysis from lakes with annually laminated sediments. Bulletin of the Ecological Society of America. 62, 126.Google Scholar
Swanson, F.J., Fire and geomorphic processes. Mooney, H.A., Bonnicksen, T.M., Christensen, N.L., Lotan, J.E., Reiners, W.A., (1981). Fire and Ecosystem Processes. United States Forest Service General Technical Report WO-26. 401-420, Washington, DC.Google Scholar
Tauber, H., (1977). Investigations of aerial pollen transport in a forested area. Dansk Botanisk Arkiv. 32, 1-121.Google Scholar
Tolonen, M., (1978). Palaeoecology of annually laminated sediments in Lake Ahvenainen, S. Finland. I. Pollen and charcoal analyses and their relation to human impact. Annales Botanicae Fennici. 15, 177-208.Google Scholar
Turco, R.P., Toon, O.B., Ackerman, T.P., Pollack, J.B., Sagan, C., (1983). Nuclear winter: Global consequences of multiple nuclear explosions. Science. 222, 1283-1292.CrossRefGoogle Scholar
Turner, J.S., (1973). Bouyancy Effects in Fluids. Cambridge Univ. Press, Cambridge.Google Scholar
Waddington, J.C.B., (1978). Vegetational Changes Associated with Settlement and Land Clearance in Minnesota over the Last 125 Years: A Comparison of Historical and Sedimentary Records. Ph.D. thesis. University of Minnesota.Google Scholar
Waring, R.H., Schlesinger, W.H., (1985). Forest Ecosystems: Concepts and Management. Academic Press, New York.Google Scholar
Winkler, M.J., (1985). Charcoal analysis for paleoenvironmental interpretation: A chemical assay. Quaternary Research. 23, 313-326.Google Scholar
Wright, R.F., (1974). Forest Fire: Impact on the Hydrology, Chemistry, and Sediments of Small Lakes in Northeastern Minnesota. Ph.D. thesis. University of Minnesota.Google Scholar