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The study of global atmospheric pollution in Antarctica

Published online by Cambridge University Press:  27 October 2009

Extract

Waste products from man's activities, released into the environment, distribute themselves between the atmosphere, the land, the sea and, through these, to the biota. There is a constant interchange of material between reservoirs leading, it is thought, to an ultimate sinking of trace materials into the depths of the ocean where they slowly accumulate on the ocean bed and are removed from the circulation system. Substances released into the air can rise into the upper atmosphere and spread all over the world before they finally sediment into the lower atmosphere and suffer washout. The overall lifetime of a particular pollutant is determined by its concentration in each reservoir and by its rate of transfer between different pairs of reservoirs. A major goal for scientists is to achieve a quantitative description of this process for the major pollutants so that in the future it may be possible to predict the changing concentrations with time, in each reservoir, of a potentially harmful pollutant of known input rate into the environment.

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Articles
Copyright
Copyright © Cambridge University Press 1975

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References

Lovelock, J. E. and others. 1973. Halogenated hydrocarbons in and over the Atlantic. By Lovelock, J. E., Maggs, R. J., and Wade, R. J.. Nature, Vol 241, p 194–96.CrossRefGoogle Scholar
Murozumi, M. and others. 1969. Chemical concentration of pollutant lead aerosols, terrestrial dusts and sea salts in Greenland and Antarctic snow strata. By Murozumi, M., Chow, T. J., and Patterson, C.. Geochimica Cosmochimica Ada, Vol 33, p 1247–94.CrossRefGoogle Scholar
Peel, D. A. 1975. Organochlorine residues in Antarctic snow. Nature, Vol 254, p 324–25.CrossRefGoogle Scholar
Peterle, T. J. 1969. DDT in Antarctic snow. Nature, Vol 224, p 620.CrossRefGoogle ScholarPubMed
Risebrough, R. W. and Carmignani, G. M. 1972. Chlorinated hydrocarbons in Antarctic birds. In: Parker, B. C. ed. Proceedings...Conservation problems in Antarctica. Lawrence, Kansas, Allen Press Inc, p 6380.Google Scholar
Wilkniss, P. E. and others. 1973. Atmospheric trace gases in the Southern Hemisphere. By Wilkniss, P. E., Lamontagne, R. A., Larson, R. E., Swinnerton, J. W., Dickson, C. R., and Thompson, T.. Nature, Vol 245, p 4547.Google Scholar
Zoller, W. H. and others. 1974. Atmospheric concentrations and sources of trace metals at the South Pole. By Zoller, W. H., Gladney, E. S., and Duce, R. A.. Science, Vol 183, No 4121, p 198200.CrossRefGoogle ScholarPubMed