Abstract
Large but feasible increases that have been projected for the production of wood energy in the United States can be expected to significantly alter the current carbon storage patterns in US forest vegetation. The 1976 net wood increment left after forest cutting equals about 136 × 106 tons of carbon/year, with about 60% of the increment found in merchantable trees, and the remainder in nonmerchantable components.
Achieving 5–10 quads of wood energy beyond 1976 levels by the year 2010 can significantly change current carbon storage patterns with the magnitude of change dependent on the extent of residue harvest to meet energy goals, and the rate of future forest growth. Complete loss of the apparent net wood increment is a possible outcome.
Although the future growth and harvest situation cannot be known now, a range of possible scenarios suggests that US forests in the year 2010 will store much less carbon than today, thus significantly changing their role in the global carbon cycle.
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Literature Cited
Armentano, T. V., and O. L. Loucks. 1982. Prospective significance of temperate zone carbon pool transients, 1980–2010. Pages 73–95.in S. Brown (ed.), Global dynamics of Biosphere carbon. Proceedings of Symposium held at Ecological Society of America/American Institute of Biological Sciences annual meeting, Bloomington, IN, 17 August 1981. Carbon Dioxide Effects Research Division, US Department of Energy CONF-8108131.
Armentano, T. V., and C. W. Ralston. 1980. The role of temperate zone forests in the global carbon cycle.Can. J. For. Res. 10:53–60.
Bethel, J. S., D. G. Briggs, L. Garay, S. P. Gessel, W. D. Kitto, W. F. Lake, A. J. Rossi, G. F. Schreuder, D. A. Tillman, and L. G. Zuller. 1979. Energy from wood. College of Forest Resources, University of Washington. A report to the Office of Technology Assessment, Congress of the United States, Washington, DC. 320 pp.
Bramryd, T. 1979. The effects of man on the biogeochemical cycle of carbon in terrestrial ecosystems. Pages 183–218in B. Bolin, E. T. Degens, S. Kempe, and P. Ketner (eds), SCOPE 13: the global carbon cycle. Scientific Committee on Problems of the Environment of the International Council of Scientific Unions. John Wiley and Sons, Chichester, UK. 490 pp.
Bureau of National Affairs. 1981. Energy users report 7-2-81.
Burwell, C. C. 1978. Solar biomass energy: an overview of U.S. potential.Science 199:1141–1148.
Cooper, C. F. 1983. Carbon storage in managed forests.Can. J. For. Res. 13:155–166.
Darr, D. R., and G. R. Lindell. 1980. Prospects for U.S. trade in timber products.For. Products J. 30:16–20.
Delcourt, H. R., and W. F. Harris. 1980. Carbon budget of the southeastern United States biota: analysis of historic change in trend from source to sink.Science 210:321–323.
Detwiler, R. P., C. Hall, and P. Bogdonoff. 1982. Simulating the impact of tropical land use changes on the exchange of carbon between vegetation and the atmosphere. Pages 141–159in S. Brown (ed.), Global dynamics of biospheric carbon. Proceedings of symposium held at Ecological Society of America/American Institute of Biological Sciences annual meeting, Bloomington, IN, 17 August 1981. Carbon Dioxide Research Division US Department of Energy CONF-8108131.
Forest Service. 1982. An analysis of the timber situation in the United States 1952-2030. US Department of Agriculture, US Forest Service, Forest Resource Report no. 23.
Hewett, D. E., C. J. High, N. Marshall, and R. Wildermuth. 1981. Wood energy in the United States.Annu. Rev. Energy 6:139–170.
Houghton, R. A., J. P. Hobbie, J. M. Melillo, B. Moore, B. J. Peterson, G. P. Shaver, and G. M. Woodwell. 1983. Changes in the carbon content of terrestrial biota and soils between 1860 and 1980: a net release of CO2 to the atmosphere.Ecol. Monographs 53:235–262.
Johnson, W. C., and D. M. Sharpe. 1983. The ratio of total to merchantable forest biomass and its application to the global carbon budget.Can. J. For. Res. 13:372–383.
Loucks, O. L. 1980. Recent results from studies of carbon cycling in the biosphere. Pages 3–42in L. E. Schmitt (ed.), Proceedings of the carbon dioxide and climate research program conference. Carbon Dioxide Effects Research and Assessment Program, Washington, DC, 24–25 April 1980. US Department of Energy, CONF-8004110 UC-11.
MITRE Corporation. 1977. Silviculture biomass farms. Report to the US Department of Energy, 6 vols.
National Research Council. 1976. Renewable resources for industrial materials. Commission on Renewable Resources for Industrial Materials, Board on Agriculture and Renewable Resources, Commission on Natural Resources.
National Research Council. 1983. Changing climate: report of CO2 assessment committee. Climate Research Board, National Academy of Sciences, Washington, DC.
Norwood, C. H., and W. L. Warnick. 1982. Consumption of wood fuels in the United States 1971-1980. Pages 130–181in K. Sarkanen, D. Tillman, and E. Jahn (eds.), Progress in biomass conversion, vol 3. Academic Press, New York.
Office of Technology Assessment. 1980. Energy From biological processes. Congress of the United States, Office of Technology Assessment, Washington, DC. 195 pp.
Olson, J. S. 1982. Earth's vegetation and atmospheric carbon dioxide. Pages 388–398in W. C. Clark (ed.), Carbon dioxide review 1982. Clarendon, Oxford, 1982. 469 pp.
Rodin, L. E., and N. I. Bazilevitch. 1967. Production and mineral cycling in terrestrial vegetation. Oliver and Boyd, London.
Rose, D., K. Ferguson, D. C. Lothner, and J. Zavitkovski. 1981. An economic and energy analysis of poplar intensive cultures in the Lake States. US Department of Agriculture Forest Service Research Paper NC-196. North Central Forest Experiment Station.
Rotty, R. 1979. Atmospheric CO2 consequences of heavy dependence on coal.Environ. Health Perspect. 33:273–283.
Sharpe, D. N., and W. C. Johnson. 1981. Land use and carbon storage in Georgia forests.J. Environ. Manage. 12:221–233.
Skog, F. E., and T. A. Watterson. 1983. Residential fuelwood use in the U.S.: 1980-81. Presentation at the international conference on renewable resources inventories for monitoring changes and trends. Co-sponsored by Society of American Foresters, International Society of Tropical Foresters, Society for Wildlife Management, International Union of Forestry Research Organizations, Renewable Natural Resources Foundation in cooperation with FAO/UN, US Forest Service and Oregon State University, Corvallis, OR.
Spurr, S., and H. Vaux. 1976. Timber: biological and economic potential.Science 191:752–756.
Tillman, D. A. 1978. Wood as an energy source. Academic Press, New York. 252 pp.
Tillman, D. A. 1982. The cost of electricity from silvicultural fuel farm-based power plants. Pages 253–274in W. R. Smith (ed.), Energy from forest biomass. 12th IUFRO world congress energy group proceedings. Academic Press, New York. 279pp.
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Armentano, T.V. Effects of increased wood energy consumption on carbon storage in forests of the United States. Environmental Management 8, 529–538 (1984). https://doi.org/10.1007/BF01871578
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DOI: https://doi.org/10.1007/BF01871578