Hostname: page-component-8448b6f56d-sxzjt Total loading time: 0 Render date: 2024-04-24T05:37:52.666Z Has data issue: false hasContentIssue false
  • English
  • Français

The Hydrogen Ion Concentration of Sea Water in its Biological Relations

Published online by Cambridge University Press:  11 May 2009

W. R. G. Atkins
W. R. G. Atkins
Affiliation:
Head of the Department of General Physiology at the Plymouth Laboratory.
Get access Rights & Permissions [Opens in a new window]

Extract

It has long been known that sea water is alkaline and numerous determinations of its alkalinity have been made. The method adopted was the usual one for mixtures of carbonates and bicarbonates, or some modification of it. Those waters which give no colour with phenolphthalein contain bicarbonate only, but for the most part ocean waters have a small amount of carbonate also. Owing to the presence of larger amounts of carbonates and bicarbonates the reaction of sea water is more stable than that of rain or river water, inasmuch as it has a greater alkaline reserve which acts as a “buffer.” The significance of this has been pointed out by Moore, Prideaux, and Herdman (1915) and by other workers. The measurement of alkalinity was carried out by the above named using N/100 hydrochloric acid and titrating to the end points with phenol phthalein and methyl orange. The results are recorded in cubic centimetres of centinormal acid per 100 c.c. of sea water; this is convenient as it is what is measured directly, but others adopt the perhaps more rational notation of milligram equivalents of hydroxyl per litre (Buch, 1914). One cubic centimetre of N/100 acid per 100 c.c. corresponds to 0.1 milligram equivalent per litre. Some workers on fresh waters, Birge and Juday (1911) for example, consider water as acid if it contains more carbon dioxide than that sufficient to convert the carbonate into bicarbonate, and titrate back to a pink with phenolphthalein. Their acid water is, however, still alkaline to methyl orange.

Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 12 , Issue 4 , October 1922 , pp. 717 - 771
Copyright
Copyright © Marine Biological Association of the United Kingdom 1922

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Atkins, W. R. G. 1922. Some factors affecting the hydrogen ion concentration of the soil and its relation to plant distribution. Sci. Proc. Roy. Dublin Soc., 16, No. 30, 369412.Reprinted in Notes from the Botanical School of Trinity College, Dublin, 1922, 3, No. 3.Google Scholar
Bayliss, W. M. 1915. Principles of general physiology. London.CrossRefGoogle Scholar
Beans, H.T., and Oakes, E.T. 1920. The determination of the hydrogenion concentration of pure water by a method for measuring the electro-motive force of concentration cells of high internal resistance. J. Amer. Chem. Soc., 42, 2116.CrossRefGoogle Scholar
Birge, E. A., and Juday, C. 1911. The inland lakes of Wisconsin. The dissolved gases of the water and their biological significance. Wisconsin Geol. and Nat. Hist. Survey. Madison, Wis.Google Scholar
Buch, K. 1914. Über die Alkalinität, Kohlensäure und Wasserstoffionenkonzentration in der Pojowiek. Fennia, Bull. de la Soc. degéographie de Finlande, 35, No. 3.Google Scholar
1917. Buch, K.Über die Alkalinität, Wasserstoffionenkonzentration, Kohlensäure und Kohlensäuretension in Wasser der Finland umgebenden Meere. Soc. Scient. Fennica, Finländische hydrographisch-biologische Unitersuchungen, No. 14, p. 135.Google Scholar
Cameron, F. K., and Briggs, L. J. 1901. Equilibrium between carbonates and bicarbonates in aqueous solution. J. Phys. Chem., 5, 537.CrossRefGoogle Scholar
Chambers, C. O. 1912. The relation of algæ to dissolved oxygen and carbon dioxide, with special reference to carbonates. 23rd Ann. Report, Missouri Bot. Gardens, 171207.Google Scholar
Clark, W. M. 1920. The determination of hydrogen ions. Baltimore.Google Scholar
1921.Clark, W. M.Reply to Wherry and Adams' article on methods of stating acidity. J. Wash. Acad. Sci., 11, 199.Google Scholar
Cole, S. W. 1920. Practical physiological chemistry. Cambridge.Google Scholar
Gail, F. W. 1918. Some experiments with Fucus to determine the factors controlling its vertical distribution. Publ. Puget Sound Biol. Sta., 2, 139.Google Scholar
1919.Gail, F. W.Hydrogen ion concentration and other factors affecting the distribution of Fucus. Loc. cit., 2, 287.Google Scholar
Hall, A. R. 1918. Some experiments on the resistance of sea-urchin eggs to sulphurous acid. Publ. Puget Sound Biol. Sta., 2, 113.Google Scholar
Helland-Hansen, B. 1914. Eine Untersuchungsfahrt im Atlantischen Ozean mit dem Motorschiff “Armauer Hansen” im Sommer 1913. Internat. Rev. d. ges. Hydrobiol. u. Hydrogr. 7, 61.Google Scholar
Kanitz, A. 1915. Temperature und Lebensvorgäange. Berlin.Google Scholar
Matthaei, G. L. C. 1905. Experimental researches on vegetable assimilation and respiration. III, On the effect of temperature on carbondioxide assimilation. Phil. Trans. Roy. Soc. B. 197. 47–105.Google Scholar
Mayer, A. G. 1916. Sub-marine solution of limestone in relation to the Murray-Agassiz theory of coral atolls. Proc. Nat. Acad. Sci., U.S.A., 2, 28.CrossRefGoogle Scholar
Mayer, A. G. 1919. Detecting ocean currents by observing their hydrogen ion concentration. Proc. Amer. Phil. Soc., 58, 150.Google Scholar
McClendon, J. F. 1916. On changes in the sea and their relation to organisms. Dept. of Marine Biol., Carnegie Inst., Washington, 12, 213–58. Carnegie Publ. No. 252.Google Scholar
McClendon, J. F. 1917. The standardisation of a new colorimetric method for the determination of the hydrogen ion concentration, CO2 tension, and CO2 and CO2 content of sea water, of animal heat, and of CO2 of the air, with a summary of similar data on bicarbonate solutions in general. J. Biol. Chem., 30, 265–88.CrossRefGoogle Scholar
Michael, E. L. 1921. Effect of upwelling water upon the organic fertility of the sea in the region of Southern California. Special Publications of B.P. Bishop Museum, No. 7, 555– 95.Google Scholar
Moore, B., Edie, E. S., Whitley, E., and Dakin, W. J. 1912. The nutrition and metabolism of marine animals in relationship to (a) Dissolved organic matter and (b) Particulate organic matter of sea water. Biochem. J., 6, 255.CrossRefGoogle Scholar
Moore, , Edie, , and Whitley, , 1913. The nutrition and metabolism of marine animals; the rate of oxidation and output of carbon dioxide in marine animals in relation to the available supply of food in sea water. Rep. Lancashire Sea Fisheries, Liverpool, 22, 297.Google Scholar
Moore, B., Prideaux, E. B. R., and Herdman, G. A. 1915. Studies of certain photosynthetic phenomena in sea water. Proc. & Trans. Liverpool Biol. Soc., 29, 233– 64.Google Scholar
Moore, B., and Webster, T. A. 1920. Studies of photosynthesis in fresh-water algæ. Proc. Roy. Soc., B. 91, 201.Google Scholar
Moore, B., Whitley, E., and Webster, T. A. 1921. Studies of photosynthesis in marine algæ. Proc. Roy. Soc., B. 92, 51.Google Scholar
Morgulis, S., and Fuller, E. W. 1916. Can CO2 in sea water be directly determined by titration? J. Biol.Chem., 24, 31.CrossRefGoogle Scholar
Nansen, F. 1915. Spitzbergen Waters. Videnskaps-Selskapets Skrifter. I. Math. naturv. Klasse, No. 2, 1132.Google Scholar
Powers, E. B. 1914. The reactions of cray fishes to gradients of dissolved carbon dioxide and acetic and hydrochloric acids. Biol. Bull., 27, 177.CrossRefGoogle Scholar
Powers, E. B. 1920. The variation of the condition of sea water, especially the hydrogen ion concentration, and its relation to marine organisms. Publ. Puget Sound Biol. Sta., 2, 369.Google Scholar
Powers, E. B. 1921. Experiments and observations on the behaviour of marine fishes toward hydrogen ion concentration of the sea water in the relation to their migratory movements and habits. Loc. cit., 3, 1.Google Scholar
Powers, E. B. 1922. The physiology of the respiration of fishes in relation to the hydrogen ion concentration of the medium. J. Gen. Physiol., 4, 305.Google Scholar
Prideaux, E. B. R. 1919. The effect of sea salt on the pressure of carbon dioxide and alkalinity of natural waters. J. Chem. Soc., 115, 1223.CrossRefGoogle Scholar
Roaf, H. E. 1920. Graphic conversion of Sörensen's pH (—log H) into concentrations of hydrogen ions. J. Physiol., 54, p. xvii.Google Scholar
Schloesing, Th. 1872. Sur la dissolution du carbonate de chaux par l'acide carbonique. Compt. Rend., 74, 1552, 75, 70.Google Scholar
Schmidt, C. L. A., and Hoagland, D. R. 1919. Table of PH, H+, and OH- values corresponding to electromotive forces determined in hydrogen electrode measurements, with a bibliography. Univ. of California, Publ. in Physiology, 5, No. 4, 2369.Google Scholar
Shelford, V. E. 1918. The relation of marine fishes to acids with particular reference to the Miles Acid Process of sewage treatment. Publ. Puget Sound Biol. Sta., 2, 97.Google Scholar
Walker, J., and Kay, S. A. 1912. The acidity and alkalinity of natural waters. J. Soc. Chem. Ind., 31, 1013.Google Scholar
Wells, R. C. 1915. The solubility of calcite in water in contact with the atmosphere and its variation with temperature. J. Wash. Acid. Sci., 5, 617.Google Scholar
Wells, R. C. 1918. The solubility of calcite in sea water in contact with the atmosphere, and its variation with temperature. Dept. of Marine Biol., Carnegie Inst., Washington, 9, 316. Carnegie Publ., No. 213.Google Scholar
Wells, R. C. 1920. The salt error of cresol red. J. Amer. Chem. Soc., 42, 1260.CrossRefGoogle Scholar
Wherry, E. T., 1919. The statement of acidity and alkalinity with special reference to soils. J. Wash. Acad. Sci., 9, 305.Google Scholar
Wherry, E. T., and Adams, E. Q. 1921. Methods of stating acidity. J. Wash. Acad. Sci., 11, 197.Google Scholar