Nonrenewable Resources

, Volume 5, Issue 4, pp 211–233 | Cite as

The material flow concept for materials

  • Dennis S. Kostick


Mineral supply and demand data were used to track the flow of a material from its source through stages of production, processing, and fabrication into the consumption and postconsumption phases. In each stage prior to consumption, the quantity of material lost to the environment or recovered for reuse was determined. In the postconsumption stage, the quantity of material discarded was analyzed to determine how much was disposed to landfills, lost through incineration, or dispersed to the environment. Where the consumption stage involved releases to the environment, as in the use of fertilizer, this was noted also. The material flow studies also strived to determine the amount of recycling that was done in the preconsumption and postconsumption phases. Cumulative historical supply data were used to estimate the total inventory of the materials that have been put into service within the United States, and aggregated consumption data based on end use provided a basis for assessing the cumulative effect of those materials on the environment.

Key Words

Mateeial flow production consumption 


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  1. Ayres, R. U., and A. V. Kneese, 1989, Industrial metabolism—Technology production, consumption, and environment: National Academy Press, p. 23–49.Google Scholar
  2. Burruss, R. P., and D. H. Sargent, 1976, Technical and microeconomic analysis of arsenic and its compounds: National Technical Information Service PB-253-980, 228 p.Google Scholar
  3. Curwick, L. R., W. A. Petersen, and H. V. Makar, 1980, Availability of critical scrap metals containing chromium in the United States-Superalloys and cast heat- and corrosionresistant alloys: U.S. Bureau of Mines Information Circular 8821, 51 p.Google Scholar
  4. Davis, W. E., and Associates, 1971, National inventory of sources and emissions: arsenic-1968: National Technical Information Service PB-220-619, Springfield, Virginia, 51 p.Google Scholar
  5. Edwards, A. M., 1990, Dependence of alloy producers on international strategic minerals,in Kessel, K. A., ed., Strategic minerals: U.S. alternatives: National Defense University Press, p. 122–123.Google Scholar
  6. Franklin Associates Ltd., 1990, Characterization of plastic products in municipal solid waste: A study prepared for the Council for Solid Waste Solutions, Praire Village, Kansas, p. 1–2.Google Scholar
  7. Franklin Associates Ltd., 1992, Characterization of municipal solid waste in the United States-1992 Update: U.S. Environmental Protection Agency, EPA/530-SW-92-019, 142 p.Google Scholar
  8. Jolly, J. H., 1992, Materials flow of zinc in the United States 1850–1990: U.S. Bureau of Mines, Open-File-Report 72-92, 53 p.Google Scholar
  9. Kieffer, B. F., 1982, Recycling systems with particular reference to the zinc process,in Tungsten 1982: Proceedings of the Second International Tungsten Symposium, San Francisco, June 1982, p. 102–114.Google Scholar
  10. Kostick, D. S., 1993, The material flow of salt: U.S. Bureau of Mines Information Circular 9343, 32 p.Google Scholar
  11. Leaversuch, R. D., 1991, Chemical recycling brings real versatility to solid-waste management: Modern Plastics, v. 68, no. 7, p. 42–43.Google Scholar
  12. Loebenstein, J. R., 1994, The material flow of arsenic in the United States: U.S. Bureau of Mines Information Circular 9382, 12 p.Google Scholar
  13. National Academy of Sciences, 1977, Arsenic: Medical and biologic effects of environmental pollutants: National Research Council, 332 p.Google Scholar
  14. National Commission on Materials Policy, 1973, Material needs and the environment today and tomorrow: Final Report, June 1973, 306 p.Google Scholar
  15. National Materials Advisory Board, 1983, Cobalt conversion through technological alternatives: National Research Council, U.S. Bureau of Mines Contract J0113103, National Academy Press NMAB-406, 204 p.Google Scholar
  16. Roskill Information Services, 1989, The economics of cobalt, 6th Ed., 244 p.Google Scholar
  17. Shedd, K. B., 1993, The materials flow of cobalt in the United States: U.S. Bureau of Mines Information Circular 9350, 26 p.Google Scholar
  18. Society of Environmental Toxicology and Chemistry, 1991, A technical framework for life-cycle assessment, 134 p.Google Scholar
  19. Tanner, A. O., The materials flow of plastic polymers in the United States: unpublished report.Google Scholar
  20. U.S. Environmental Protection Agency, 1983, Inorganic arsenic emissions from low-arsenic primary copper smelters—Background information for proposed standards: Office of Air Quality, 467 p.Google Scholar

Copyright information

© International Association for Mathematical Geology 1996

Authors and Affiliations

  • Dennis S. Kostick
    • 1
  1. 1.National Center 983U.S. Geological SurveyReston

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