Geologic history of sea water

Paleontology and biochemistry together may yield fairly definite information, eventually, about the paleochemistry of sea water and atmosphere. Several less conclusive lines of evidence now available suggest that the composition of both sea water and atmosphere may have varied somewhat during the past; but the geologic record indicates that these variations have probably been within relatively narrow limits. A primary problem is how conditions could have remained so nearly constant for so long. It is clear, even from inadequate data on the quantities and compositions of ancient sediments, that the more volatile materials—H 2 O, CO 2 , Cl, N, and S— are much too abundant in the present atmosphere, hydrosphere, and biosphere and in ancient sediments to be explained, like the commoner rock-forming oxides, as the products of rock weathering alone. If the earth were once entirely gaseous or molten, these “excess” volatiles may be residual from a primitive atmosphere. But if so, certain corollaries should follow about the quantity of water dissolved in the molten earth and the expected chemical effects of a highly acid, primitive ocean. These corollaries appear to be contradicted by the geologic record, and doubt is therefore cast on this hypothesis of a dense primitive atmosphere. It seems more probable that only a small fraction of the total “excess” volatiles was ever present at one time in the early atmosphere and ocean. Carbon plays a significant part in the chemistry of sea water and in the realm of living matter. The amount now buried as carbonates and organic carbon in sedimentary rocks is about 600 times as great as that in today9s atmosphere, hydrosphere, and biosphere. If only 1/100 of this buried carbon were suddenly added to the present atmosphere and ocean, many species of marine organisms would probably be exterminated. Furthermore, unless CO 2 is being added continuously to the atmosphere-ocean system from some source other than rock weathering, the present rate of its subtraction by sedimentation would, in only a few million years, cause brucite to take the place of calcite as a common marine sediment. Apparently, the geologic record shows no evidence of such simultaneous extinctions of many species nor such deposits of brucite. Evidently the amount of CO 2 in the atmosphere and ocean has remained relatively constant throughout much of the geologic past. This calls for some source of gradual and continuous supply, over and above that from rock weathering and from the metamorphism of older sedimentary rocks. A clue to this source is afforded by the relative amounts of the different “excess” volatiles. These are similar to the relative amounts of the same materials in gases escaping from volcanoes, fumaroles, and hot springs and in gases occluded in igneous rocks. Conceivably, therefore, the hydrosphere and atmosphere may have come almost entirely from such plutonic gases. During the crystallization of magmas, volatiles such as H 2 O and CO 2 accumulate in the remaining melt and are largely expelled as part of the final fractions. Volcanic eruptions and lava flows have brought volatiles to the earth9s surface throughout the geologic past; but intrusive rocks are probably a much more adequate source of the constituents of the atmosphere and hydrosphere. Judged by the thermal springs of the United States, hot springs (carrying only 1 per cent or less of juvenile matter) may be the principal channels by which the “excess” volatiles have escaped from cooling magmas below. This mechanism fails to account for a continuous supply of volatiles unless it also provides for a continuous generation of new, volatile-rich magmas. Possibly such local magmas form by a continuous process of selective fusion of subcrustal rocks, to a depth of several hundred kilometers below the more mobile areas of the crust. This would imply that the volume of the ocean has grown with time. On this point, geologic evidence permits differences of interpretation; the record admittedly does not prove, but it seems consistent with, an increasing growth of the continental masses and a progressive sinking of oceanic basins. Perhaps something like the following mechanism could account for a continuous escape of volatiles to the earth9s surface and a relatively uniform composition of sea water through much of geologic time: (1) selective fusion of lower-melting fractions from deep-seated, nearly anhydrous rocks beneath the unstable continental margins and geosynclines; (2) rise of these selected fractions (as granitic and hydrous magmas) and their slow crystallization nearer the surface; (3) essentially continuous isostatic readjustment between the differentiating continental masses and adjacent ocean basins; and (4) renewed erosion and sedimentation, with resulting instability of continental margins and mountainous areas and a new round of selective fusion below.

[1]  N. L. Bowen The evolution of the igneous rocks , 1956 .

[2]  F. A. Pitelka,et al.  PRINCIPLES OF ANIMAL ECOLOGY , 1951 .

[3]  L. G. Weeks Concerning estimates of potential oil reserves , 1950 .

[4]  W. Bucher Megatectonics and geophysics , 1950 .

[5]  D. White,et al.  The sources of heat and water supply of thermal springs, with particular reference to Steamboat Springs, Nevada , 1950 .

[6]  J. B. Carsey Geology of Gulf Coastal Area and Continental Shelf , 1950 .

[7]  J. Wilson Recent applications of geophysical methods to the study of the Canadian Shield , 1950 .

[8]  Karl P. Schmidt,et al.  Principles of Animal Ecology , 1950 .

[9]  Hugo Benioff,et al.  SEISMIC EVIDENCE FOR THE FAULT ORIGIN OF OCEANIC DEEPS , 1949 .

[10]  H. Suess Die Häufigkeit der Edelgase Auf Der Erde Und Im Kosmos , 1949, The Journal of Geology.

[11]  W. D. Urry Significance of radioactivity in geophysics ‐ Thermal history of the Earth , 1949 .

[12]  W. Wahl Isostasy and the origin of sial and sima and of parental rock magmas , 1949 .

[13]  M. Hubbert,et al.  Energy from Fossil Fuels. , 1949, Science.

[14]  L. Ahrens MEASURING GEOLOGIC TIME BY THE STRONTIUM METHOD , 1949 .

[15]  D. Gibson The terrestrial distribution of the elements , 1949 .

[16]  K. Rankama NEW EVIDENCE OF THE ORIGIN OF PRE-CAMBRIAN CARBON , 1948 .

[17]  S. Miholić Ore deposits and geologic age , 1947 .

[18]  G. P. Baxter,et al.  The Determination of the Gases in Meteoritic and Terrestrial Irons and Steels , 1947 .

[19]  H. Landsberg Note on the frequency distribution of geothermal gradients , 1946 .

[20]  H. W. Harvey Recent Advances In The Chemistry And Biology Of Sea Water , 1946 .

[21]  E. Rabinowitch,et al.  Photosynthesis and Related Processes , 1946 .

[22]  A. C. Giese Ultraviolet Radiations and Life , 1945, Physiological Zoology.

[23]  E. Rabinowitch Chemistry of photosynthesis, chemosynthesis and related, processes in vitro and in vivo , 1945 .

[24]  C. Cotton Volcanic Contributions to the Atmosphere and Ocean , 1944, Nature.

[25]  W. T. Edmondson Ecological Studies of Sessile Rotatoria: Part I. Factors Affecting Distribution , 1944 .

[26]  Martin W. Johnson,et al.  The oceans : their physics, chemistry, and general biology , 1943 .

[27]  N. Keevil Radiogenic Heat in Rocks , 1943, The Journal of Geology.

[28]  R. Daly The Floor of the Ocean , 1943 .

[29]  G. Dobson 3. Atmospheric radiation and the temperature of the lower stratosphere , 1942 .

[30]  M. D. Foster Base-Exchange and Sulphate Reduction in Salty Ground Waters Along Atlantic and Gulf Coasts , 1942 .

[31]  R. Wildt The Geochemistry of the Atmosphere and the Constitution of the Terrestrial Planets , 1942 .

[32]  H. Spicer Observed Temperatures in the Earth’s Crust , 1942 .

[33]  F. Birch,et al.  Handbook of physical constants , 1942 .

[34]  E. Ingerson,et al.  Nature of the ore-forming fluid; a discussion , 1940 .

[35]  H. N. Russell THE TIME-SCALE OF THE UNIVERSE. , 1940 .

[36]  K. E. Bullen,et al.  The problem of the earth's density variation , 1940 .

[37]  A. Benfield Thermal measurements and their bearing on crustal problems , 1940 .

[38]  T. W. Vaughan Ecology of modern marine organisms with reference to paleogeography , 1940 .

[39]  L. Rayleigh Nitrogen, Argon and Neon in the Earth's Crust with Applications to Cosmology , 1939 .

[40]  A. L. Day The hot-spring problem , 1939 .

[41]  W. M. Latimer,et al.  The oxidation states of the elements and their potentials in aqueous solutions , 1938 .

[42]  L. Cooper Some Conditions Governing the Solubility of Iron , 1937 .

[43]  P. Kuenen On the total amount of sedimentation in the deep sea , 1937 .

[44]  J. Gilluly The water content of magmas , 1937 .

[45]  N. D. Stearns,et al.  Thermal springs in the United States , 1937 .

[46]  R. Moore Stratigraphic evidence bearing on problems of continental tectonics , 1936 .

[47]  R. L. Rutherford Geologic age of potash deposits , 1936 .

[48]  A. Krogh Conditions of Life in the Ocean , 1934 .

[49]  D. Menzel,et al.  The Terrestrial Abundance of the Permanent Gases. , 1933, Proceedings of the National Academy of Sciences of the United States of America.

[50]  W. Russell Subsurface Concentration of Chloride Brines , 1933 .

[51]  F. A. Davidson Temporary High Carbon Dioxide Content in an Alaskan Stream at Sunset , 1933 .

[52]  W. Hoover Carbon dioxide assimilation in a higher plant , 1933 .

[53]  P. Eskola On the origin of granitic magmas , 1932 .

[54]  A. Lawson Insular Arcs, Foredeeps, and Geosynclinal Seas of the Asiatic Coast , 1932 .

[55]  W. H. Twenhofel Magnitude of the Sediments Beneath the Deep Sea , 1929 .

[56]  J. Maynard,et al.  Solution, transportation and precipitation of iron and silica , 1929 .

[57]  J. Barrell On continental fragmentation and the geologic bearing of the moon's surficial features , 1927 .

[58]  H. S. Pruthi The Ability of Fishes to Extract Oxygen at Different Hydrogen Ion Concentrations of the Medium , 1927, Journal of the Marine Biological Association of the United Kingdom.

[59]  C. Fenner The Katmai Magmatic Province , 1926, The Journal of Geology.

[60]  W. Collins,et al.  Michipicoten Iron Ranges , 1926 .

[61]  H. Jeffreys The Rare Gases of the Atmosphere , 1924, Nature.

[62]  F. W. Aston The Rarity of the Inert Gases on the Earth , 1924, Nature.

[63]  O. E. Meinzer Origin of the Thermal Springs of Nevada, Utah, and Southern Idaho , 1924, The Journal of Geology.

[64]  W. R. G. Atkins The Hydrogen Ion Concentration of Sea Water in its Biological Relations , 1922, Journal of the Marine Biological Association of the United Kingdom.

[65]  J. W. Gruner Organic matter and the origin of the Biwabik iron-bearing formation of the Mesabi range , 1922 .

[66]  J. Evans A modern theory of the Earth , 1919 .

[67]  J. Mcclendon THE COMPOSITION, ESPECIALLY THE HYDROGEN ION CONCENTRATION, OF SEA WATER IN RELATION TO MARINE ORGANISMS , 1916 .

[68]  L. Henderson The Fitness of the Environment: An Inquiry Into the Biological Significance of the Properties of Matter , 1913 .

[69]  J. Johnston,et al.  The General Principles Underlying Metamorphic Processes , 1913, The Journal of Geology.

[70]  L. Adams,et al.  Effect of high pressures on the physical and chemical behavior of solids , 1913 .

[71]  L. Henderson The fitness of the environment , 1913 .

[72]  J. Walther Origin and peopling of the deep sea , 1911 .

[73]  R. Daly First calcareous fossils and the evolution of the limestones , 1909 .

[74]  Horace Tabberer Brown,et al.  Researches on some of the Physiological Processes of Green Leaves, with Special Reference to the Interchange of Energy between the Leaf and Its Surroundings , 1905 .

[75]  T. C. Chamberlin A Group of Hypotheses Bearing on Climatic Changes , 1897, The Journal of Geology.

[76]  A. J. Ewart On Assimilatory Inhibition in Plants , 1896 .

[77]  S. Arrhenius “On the Infl uence of Carbonic Acid in the Air upon the Temperature of the Ground” (1896) , 2017, The Future of Nature.