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Estimation of Inbuilt Age in Radiocarbon Ages of Soil Charcoal for Fire History Studies

Published online by Cambridge University Press:  18 July 2016

Daniel G Gavin
Daniel G Gavin*
Affiliation:
College of Forest Resources, University of Washington - Box 352100, Seattle, Washington 98195 USA. Email: [email protected].
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Abstract

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Radiocarbon age determinations of wood charcoal are commonly used to date past forest fire events, even though such ages should be greater than the fire event due to the age of the wood at the time of burning. The difference in the 14C-derived age of charcoal and the time-since-fire (the “inbuilt age”) may be considerable in some vegetation types and thus must be estimated before interpreting fire dates. Two methods were used to estimate the potential range of inbuilt age of soil charcoal dated to determine ages of forest fires on the west coast of Vancouver Island (Canada). First, 26 14C ages on charcoal in surficial soil were compared directly with ages of forest fire determined by tree-ring counts, suggesting inbuilt ages of 0–670 years. Second, a simulation model that uses estimated fuel loads, fuel consumption, charcoal production, and the ages of charred wood (time since wood formation), suggests that the combination of slow growth rates and slow decay rates of certain species can account for inbuilt ages of more than 400 years in this forest type. This level of inbuilt age is large enough such that the actual age of a fire may not occur within the 2σ confidence interval of a calibrated charcoal 14C age determination, and thus significantly affect the interpretation of fire dates. A method is presented to combine the error of a calibrated 14C age determination with the error due to inbuilt age such that the larger adjusted error encompasses the actual age of the fire.

Type
Articles
Information
Radiocarbon , Volume 43 , Issue 1 , 2001 , pp. 27 - 44
Copyright
Copyright © The Arizona Board of Regents on behalf of the University of Arizona 

References

Agee, JK, Huff, MH. 1987. Fuel succession in a western hemlock/Douglas-fir forest. Canadian Journal of Forest Research 17:697704.CrossRefGoogle Scholar
Agee, JK. 1993. Fire ecology of Pacific Northwest forests. Washington, D.C.: Island Press.Google Scholar
Aitken, MJ. 1990. Science-based dating in archaeology. London: Longman Group UK Limited.Google Scholar
Carcaillet, C. 1998. A spatially precise study of Holocene fire history, climate and human impact within the Maurienne valley, North French Alps. Journal of Ecology 86:384–96.CrossRefGoogle Scholar
Chandler, C, Cheney, P, Thomas, P, Trabaud, L, Williams, D. 1983. Fire in forestry, Volume I: forest fire behavior and effects. New York: John Wiley & Sons.Google Scholar
Clark, JS, Lynch, J, Stocks, BJ, Goldammer, JG. 1998. Relationships between charcoal particles in air and sediments in west-central Siberia. Holocene 8:1929.CrossRefGoogle Scholar
Daniels, LD, Marshall, PL, Klinka, K. 1995. Age structure of Thuja plicata in the tree layer of old-growth stands near Vancouver, British Columbia. Northwest Science 69:175–83.Google Scholar
Daniels, LD, Dobry, J, Klinka, K, Feller, MC. 1997. Determining the year of death of logs and snags of Thuja plicata in southwestern coastal British Columbia. Canadian Journal of Forest Research 27:1132–41.CrossRefGoogle Scholar
DeBell, DS, Franklin, F. 1987. Old-growth Douglas-fir and western hemlock: a 36-year record of growth and mortality. Western Journal of Applied Forestry 2:111–4.CrossRefGoogle Scholar
Fahnestock, GR, Agee, JK. 1983. Biomass consumption and smoke production by prehistoric and modern forest fires in western Washington. Journal of Forestry 81:653–7.Google Scholar
Gavin, DG. 2000. Holocene fire history of a coastal temperate rain forest, Vancouver Island, British Columbia. PhD dissertation, University of Washington, Seattle.Google Scholar
Gholz, HL, Grier, CC, Campbell, AG, Brown, AT. 1979. Equations for estimating biomass and leaf area of plants in the Pacific Northwest. Research Paper 41. Oregon State University Forest Research Lab. Google Scholar
Graham, RL, Cromack, K Jr. 1982. Mass, nutrient content and decay rate of dead boles in rain forests of Olympic National Park. Canadian Journal of Forest Research 12:511–21.CrossRefGoogle Scholar
Harmon, ME, Franklin, JF, Swanson, FJ, Sollins, P, Gregory, SV, Lattin, JD, Anderson, NH, Cline, SP, Aumen, NG, Sedell, JR, Lienkaemper, GW, Cromack, K Jr, Cummins, KW. 1986. Ecology of coarse woody debris in temperate ecosystems. Advances in Ecological Research 15:133302.CrossRefGoogle Scholar
Hennon, PE, Loopstra, EM. 1991. Persistence of western hemlock and western redcedar trees 38 years after girdling at Cat Island in Southeast Alaska. Research Note PNW-RN-507, USDA Forest Service, Pacific NW Research Station.Google Scholar
Hoadley, RB. 1990. Identifying wood: accurate results with simple tools. Newtown, CT: Taunton Press.Google Scholar
Hopkins, MS, Ash, J, Graham, AW, Head, J, Hewett, RK. 1993. Charcoal evidence of the spatial extent of the Eucalyptus woodland expansions and rainforest contractions in North Queensland during the late Pleistocene. Journal of Biogeography 20:357–72.CrossRefGoogle Scholar
Horn, SP, Sanford, RL. 1992. Holocene fires in Costa-Rica. Biotropica 24:354–61.CrossRefGoogle Scholar
Huff, MH, Agee, JK. 1980. Characteristics of large lightning fires in the Olympic Mountains, Washington. Proceedings of the 6th Meteorology Conference, 22–24 April 1980, Seattle, American Meteorological Society.Google Scholar
Ishii, H, Clement, JP, Shaw, DC. 2000. Branch growth and crown form in old coastal Douglas-fir. Forest Ecology and Management 131:8191.CrossRefGoogle Scholar
Lowe, DJ, McFadgen, BG, Higham, TFG, Hogg, AG, Froggatt, PC, Nairn, IA. 1998. Radiocarbon age of the Kaharoa tephra, a key marker for late Holocene stratigraphy and archaeology in New Zealand. The Holocene 8:499507.CrossRefGoogle Scholar
McFadgen, BG. 1982. Dating New Zealand archaeology by radiocarbon. New Zealand Journal of Science 25: 379–92.Google Scholar
McFadgen, BG, Knox, FB, Cole, TRL. 1994. Radiocarbon calibration curve variations and their implications for the interpretation of New Zealand prehistory. Radiocarbon 36(2):221–36.CrossRefGoogle Scholar
Meidinger, D, Pojar, J. 1991. Ecosystems of British Columbia. British Columbia Ministry of Forests.Google Scholar
Meyer, GA, Wells, SG, Balling, RC Jr, Jull, AJT. 1992. Response of alluvial systems to fire and climate change in Yellowstone National Park. Nature 357:147–50.CrossRefGoogle Scholar
Meyer, GA, Wells, SG, Jull, AJT. 1995. Fire and alluvial chronology in Yellowstone National Park: climatic and intrinsic controls on Holocene geomorphic processes. Geological Society of America Bulletin 107:1211–30.2.3.CO;2>CrossRefGoogle Scholar
Molloy, BPJ, Burrows, CJ, Cox, JE, Johnston, JA, Wardle, P. 1963. Distribution of subfossil forest remains, eastern South Island, New Zealand. New Zealand Journal of Botany 1:6877.CrossRefGoogle Scholar
Ottmar, RD, Burns, MF, Hall, JN, Hanson, AD. 1993. CONSUME users guide. USDA Forest Service General Technical Report PNW-GTR-304.CrossRefGoogle Scholar
Pearson, AF. 2000. Natural disturbance patterns in a coastal temperate rain forest watershed, Clayoquot Sound, British Columbia. PhD dissertation, University of Washington, Seattle, Washington.Google Scholar
Pickford, SG, Fahnestock, G, Ottmar, R. 1980. Weather, fuel, and lightning fires in Olympic National Park. Northwest Science 54:92105.Google Scholar
Sandberg, DV, Ottmar, RD. 1983. Slash burning and fuel consumption in the Douglas-fir subregion. Proceedings 7th Conference Fire and Forest Meteorology, Fort Collins, Colorado, American Meteorological Society.Google Scholar
Schmidt, RL. 1970. A history of pre-settlement fires on Vancouver Island as determined from Douglas-fir ages. In: Smith, JHG, Worrall, J. Tree-ring analysis with special reference to Northwest America. Vancouver, B.C.: University of British Columbia Faculty of Forestry Bulletin No. 7:107–8.Google Scholar
Sollins, P. 1982. Input and decay of coarse woody debris in coniferous stands in western Oregon and Washington. Canadian Journal of Forest Research 12:1828.CrossRefGoogle Scholar
Sollins, P, Cline, SP, Verhoeven, T, Sachs, D, Spycher, G. 1987. Patterns of log decay in old-growth Douglas-fir forests. Canadian Journal of Forest Research 17: 1585–95.CrossRefGoogle Scholar
Spies, TA, Franklin, JF, Thomas, TB. 1988. Coarse woody debris in Douglas-fir forests of western Oregon and Washington. Ecology 69:1689–702.CrossRefGoogle Scholar
Stocks, BJ, Kauffman, JB. 1997. Biomass consumption and behavior of wildland fire in boreal, temperate, and tropical ecosystems: parameters necessary to interpret historic fire regimes and future fire scenarios. In: Clark, JS, Chachier, H, Goldammer, JG, Stocks, B. Sediment records of biomass burning and global change. Berlin: Springer Verlag. p 169–88.Google Scholar
Stone, JN, MacKinnon, A, Parminter, JV, Lertzman, KP. 1998. Coarse woody debris decomposition documented over 65 years on southern Vancouver Island. Canadian Journal of Forest Research 28:788–93.CrossRefGoogle Scholar
Stuiver, M, Reimer, PJ. 1993. Extended 14C database and revised CALIB radiocarbon calibration program. Radiocarbon 35(1):215–30.CrossRefGoogle Scholar
Stuiver, M, Reimer, PJ, Bard, E, Beck, JW, Burr, GS, Hughen, KA, Kromer, B, McCormac, G, Van der Plicht, J, Spurk, M. 1998. INTCAL98 radiocarbon age calibration, 24,000–0 cal BP. Radiocarbon 40(3):1041–83.CrossRefGoogle Scholar
Turner, J. 1984. Radiocarbon dating of wood and charcoal in an Australian forest ecosystem. Australian Forester 47:7983.CrossRefGoogle Scholar
Tyrell, CE, Crow, TR. 1994. Structural characteristics of old-growth hemlock-hardwood forests in relation to age. Ecology 75:370–86.Google Scholar
Waterbolk, HT. 1983. Ten guidelines for the archaeological interpretation of radiocarbon dates. PACT 8:5770.Google Scholar