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A Kinetic Model for the Chemical Composition of Sea Water1

Published online by Cambridge University Press:  20 January 2017

W. S. Broecker
W. S. Broecker*
Affiliation:
Lamont-Doherty Geological Observatory (Columbia University), Palisades, New York, USA
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Abstract

The thermodynamic ocean of the Sillen school offers little incentive to those who search the sedimentary record for evidence of changes in ocean chemistry during Cenozoic time. Their models predict a uniform chemical composition. However as the sediments presently accumulating in the ocean show little evidence of equilibration with the overlying water, the possibility that kinetic factors play an important role must be seriously explored. Such a model is presented in this paper. Material balance restrictions are substituted for some of the usual chemical equilibria. The role of organisms is shown to be dominant for at least some of the important components of sea salt (i.e., C, N, P, Si, …). If, as proposed here, the chemistry of sea water is dependent on rates of supply of individual components, the rate of vertical mixing in the sea, and the type of material formed by organisms, then substantial changes in the chemical composition have almost certainly taken place. Several means by which such changes might be reconstructed from chemical and isotopic measurements on marine sediments are discussed.

Type
Original Articles
Information
Quaternary Research , Volume 1 , Issue 2 , April 1971 , pp. 188 - 207
Copyright
University of Washington

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Footnotes

1

Lamont-Doherty Geological Observatory Contribution No. 1620.

References

Amit, O. (1969).. Silica content and silica-clay interactions in the water of the Dead Sea (Israel). Chemical Geology 5, 121129.Google Scholar
Bender, M. L. (1970).. Helium-uranium dating of corals. Ph.D. thesis, Columbia University, N.Y. 149 pp.Google Scholar
Bien, G. S., Rakestraw, N. W., Suess, H. E. (1963).. Radiocarbon dating of deep water of the Pacific and Indian Oceans. Bulletin of the Institute of Oceanography, Monaco 61, 1278.Google Scholar
Broecker, W. S. (1971).. Calcite accumulation rates and glacial to interglacial changes in oceanic mixing. In “The Late Cenozoic Glacial Ages.” (Turekian, K., Ed.), pp. 239265. Yale University Press, New Haven, Connecticut.Google Scholar
Broecker, W. S., and Li, Y.-H. (1970).. Interchange of water between the major oceans. Journal of Geophysical Research 75, 35453552.Google Scholar
Broecker, W. S., Thurber, D. L., Goodard, J., Ku, T.-H., Matthews, R. K., Mesolella, K. J. (1968).. Milankovitch hypothesis supported by precise dating of coral reefs and deep-sea sediments. Science 159, 297300.CrossRefGoogle ScholarPubMed
Clarke, F. W. (1924).. The data of geochemistry, 5th edition. U.S. Geological Survey Bulletin 770, 841 pp.Google Scholar
Craig, H. (1970).. Abyssal carbon 13 in the South Pacific. Journal of Geophysical Research 75, 691695.CrossRefGoogle Scholar
Dasch, E. J. (1969). Strontium isotopes in weathering profiles, deep-sea sediments, and sedimentary rocks. Geochimica et Cosmochimica Acta 33, 15211552.Google Scholar
Edmond, J. M. (1970). The carbonic acid system in sea water. Ph.D. Thesis, Univ. of California, San Diego.Google Scholar
Fenale, F., and Schaeffer, O. (1965). Helium-uranium ratios for Pleistocene and Tertiary fossil aragonites. Science 149, 312317.Google Scholar
Gregor, C. B. (1967). The geochemical behavior of sodium. Verhandeilingen der Koninklyke Nederlandse Akademie van Wetenschappen AFD. Natuurkunde Eerste Reeks Deel 24, 2.Google Scholar
Gregor, C. B. (1968). Silica balance of the ocean. Nature 219, 360361.CrossRefGoogle Scholar
Holland, H. D. (1965). The history of ocean water and its effect on the chemistry of the atmosphere. Proceedings National Academy of Sciences 53, 11731182.CrossRefGoogle Scholar
Holser, W. T., and Kaplan, I. R. (1966). Isotope geochemistry of sedimentary sulfates. Chemical Geology 1, 93135.Google Scholar
Hurley, P. M., Heezen, B. C., Pinson, W. H., and Fairbairn, H. W. (1963). K-Ar age values in pelagic sediments of the North Atlantic. Geochimica et Cosmochimica Acta 27, 393399.Google Scholar
Komura, K., and Sakanoue, M. (1967). Studies on the dating methods for Quaternary samples by natural alpha-radioactive nuclides. Science Reports of Kanazawa University 12, 2166.Google Scholar
Kroopnick, P., Deuser, W. G., and Craig, H. (1970). Carbon 13 measurements on dissolved inorganic carbon at the North Pacific (1969) Geosecs station. J. Geophys. Res. 75, 76687671.Google Scholar
Ku, T.-L. (1965). An evaluation of the U234/U238 method as a tool for dating pelagic sediments. Journal of Geophysical Research 70, 34573474.Google Scholar
Ku, T.-L. (1966). Uranium series disequilibrium in deep sea sediments. Ph.D. thesis, Columbia University.Google Scholar
Ku, T.-L. (1968). Protactinium-231 method of dating corals from Barbados Island. Journal of Geophysical Research 73, 22712276.Google Scholar
Ku, T.-L., Broecker, W. S., and Opdyke, N. (1968). Comparison of sedimentation rates measured by paleomagnetic and the ionium methods of age determination. Earth and Planetary Science Letters 4, 116.Google Scholar
Li, T.-H., Takahashi, T., and Broecker, W. S. (1969). The degree of saturation of CaCO3 in the oceans. Journal of Geophysical Research 74, 55075525.Google Scholar
Livingstone, D. A. (1963). Chemical composition of rivers and lakes. InThe Data of Geochemistry (6th ed.)” (Fleischer, M.,Ed.), Chapter 6. U.S. Geological Survey Professional Paper 440-G, 64 pp.Google Scholar
Lowenstam, H. A. (1961). Mineralogy, O18/O16 ratios, and strontium and magnesium contents of recent and fossil brachiopods and their bearing on the history of the oceans. Journal of Geology 69, 241260.Google Scholar
Mackenzie, F. T., and Garrels, R. M. (1965). Silicates-reactivity with sea water. Science 150, 5758.Google Scholar
Mackenzie, F. T., and Garrels, R. M. (1966a). Chemical mass balance between rivers and the ocean. American Journal of Science 264, 507525.Google Scholar
Mackenzie, F. T., and Garrels, R. M. (1966). Silica bicarbonate balance in the ocean and early diagenesis. Journal of Sedimentary Petrology 36, 10751084.Google Scholar
Mackenzie, F. T., Garrels, R. M., Bricker, O. P., and Buckley, F. (1967). Silica in sea water: Control by silicate minerals. Science 155, 14041405.CrossRefGoogle Scholar
Maddocks, G. E. (1967). The geochemistry of surface waters of the western district of Victoria, Aust. Journal of Marine and Freshwater Research 15, 3552.Google Scholar
McLoughlin, R. J. W. (1966). Geochemical concentration under saline conditions. Proceedings Royal Society, Victoria 79, 569577.Google Scholar
Mesolella, K. J., Matthews, R. K., Broecker, W. S., and Thurber, D. L. (1969). The astronomical theory of climate change: Barbados data. Journal of Geology 77, 250274.CrossRefGoogle Scholar
Pytkowicz, R. M., and Kester, D. R. (1967). Relative calcium phosphate saturation in two regions of the North Pacific Ocean. Limnology and Oceanography 12, 714718.Google Scholar
Redfield, A. C., Ketchum, B. H., and Richards, F. A. (1963). The influence of organisms on the composition of sea water. InThe Sea” (Hill, M. H., Ed.), Vol. 2, 2677.Google Scholar
Sackett, W. M., and Potratz, H. A. (1963).Dating of carbonate rocks by ionium-uranium ratios in subsurface geology of Eniwetok Atolls (Schlanger, S. O. Ed.). U.S. Geological Survey Professional Paper 260-BB, pp. 10531056.Google Scholar
Sackett, W. M., Eckelmann, W. R., Bender, M. L., and Be, A. W. H. (1965). Temperature dependence of carbon isotope composition in marine plankton and sediments. Science 148, 235237.CrossRefGoogle ScholarPubMed
Savin, S. M., and Epstein, S. (1970). The oxygen and hydrogen isotope geochemistry of ocean sediments and shales. Geochimica et Cosmochimica Acta 34, 4363.CrossRefGoogle Scholar
Siever, R. (1968a). Establishment of equilibrium between clays and sea water. Earth and Planetary Science Letters 5, 106110.Google Scholar
Siever, R. (1968b). Sedimentological consequences of a steady-state ocean. Atmosphere Sedimentology 11, 529.Google Scholar
Siever, R., Beck, K. C., and Berner, R. A. (1965). Composition of interstitial waters of modern sediments. Journal of Geology 73, 3973.CrossRefGoogle Scholar
Sillen, L. G. (1961). The physical chemistry of sea water. InOceanography” (Sears, M. Ed.), pp. 549581. American Association for the Advancement of Science Publication 67.Google Scholar
Sillen, L. G. (1963). How has sea water got its present composition. Svensk Kem Tideiski 75, 161177.Google Scholar
Sillen, L. G. (1967a). The ocean as a chemical system. Science 156, 11891197.Google Scholar
Sillen, L. G. (1967). Gibbs phase rule and marine sediments. InEquilibrium Concepts in Natural Water Systems” (Gould, R. F. Ed)., pp. 5769. Advanced Chemistry Series 67, American Chemical Society, London, Special Publication 17, 754 pp.Google Scholar
Simpson, H. J. (1970). Closed basin lakes as a tool in geochemistry. Ph.D. Thesis, Columbia University.Google Scholar
Thurber, D. L. (1965). The concentrations of some natural radioelements in the waters of the Great Basin. Ex Bull Volcan 38, 7 pp.Google Scholar
Thurber, D. L., Broecker, W. S., Blanchard, R. L., and Potratz, H. A. (1965). Uranium-series ages of Pacific Atoll coral. Science 149, 5558.Google Scholar
Turekian, K. K., and Armstrong, R. L. (1961). Chemical and mineralogical composition of fossil molluscan shells from the Fox Hills Formation, South Dakota. Geological Society of America Bulletin 72, 18171828.CrossRefGoogle Scholar
Van Donk, J., and Broecker, W. S. (In press). Temporal changes in the phosphorus to carbon ratio in sea salt as indicated by variations in the C13-C12 ratio in planktonic forams.Google Scholar
Veeh, H. H. (1966). Th230/U238 and U234 238 ages of Pleistocene high sea level stand. Journal of Geophysical Research 71, 33793386.Google Scholar
Veeh, H. H., and Chapell, J. (1970). Astronomical theory of climate change: support from New Guinea. Science 167, 862865.CrossRefGoogle Scholar
Veeh, H. H., and Turekian, K. K. (1968). Cobalt, silver and uranium concentrations of reef-building corals in the Pacific Ocean. Limnology and Oceanography 13, 304308.Google Scholar
Whitehead, H. C., and Feth, J. H. (1961). Recent chemical analyses of waters from several closed basin lakes and their tributaries in the western United States. Geological Society of America Bulletin 72, 14211426 Google Scholar
Wolgemuth, K., and Broecker, W. S. (1970). Barium in sea water. Earth and Planetary Science Letters 8, 372378.Google Scholar