Hostname: page-component-77c89778f8-vpsfw Total loading time: 0 Render date: 2024-07-20T21:30:10.406Z Has data issue: false hasContentIssue false
  • English
  • Français

Chemical Constituents of Biological Importance in the English Channel, November, 1930, to January, 1932. Part II. Hydrogen ion concentration, excess base, carbon dioxide, and oxygen

Published online by Cambridge University Press:  11 May 2009

L. H. N. Cooper
L. H. N. Cooper
Affiliation:
Assistant Chemist at the Plymouth Laboratory
Get access Rights & Permissions [Opens in a new window]

Extract

(1) In general, the changes in pH were similar to those observed in previous years. On six occasions the pH at the surface at Station L4 was lower than at the bottom.

(2) The changes in carbon dioxide in the spring agree with the conclusion, formed in Part I from nutrient salt data, that the early start in plant production in mid-Channel was not maintained and that by the middle of April production had become much greater nearer the shore.

(3) The partial pressure of CO2 during nine months out of twelve has been observed to be lower than that of the atmosphere and equal or slightly higher during the remaining three months.

(4) It is suggested that the fall in (Total CO2+O2) during the course of the summer was due mostly to loss of oxygen to the atmosphere. After allowing for carbon dioxide possibly removed from the sea as calcium carbonate and for the loss of oxygen due solely to rising temperature of the water, a net loss of 110 litres of oxygen was found from a column 1 sq. metre in cross-section and 70 metres deep; or 9 cubic kilometres from the whole of the Channel. If this is regarded as a closed system, the oxygen must have been formed during photosynthesis from an equal volume of CO2 dissolved from the atmosphere. But the required transfer of CO2 across the surface of the sea is too great to be accounted for by existing data on the rate of invasion of CO2 into sea-water as calculated for a small bubble of gas in water.

(5) Estimates of the phytoplankton crop have been made, based on the seasonal consumption of carbon dioxide, of phosphate and of nitrate and on the oxygen lost to the atmosphere. All four are of the order of 1,400 metric tons wet weight per sq. km. of surface, in close agreement with the figure calculated by Atkins. The crop production calculated from consumption of silicate is less than one-tenth of this. This is attributed not only to the presence of planktonic organisms requiring no silica but to the silicate being used several times over in the course of the season.

(6) About 0·06% of the wet weight of phytoplankton produced is harvested as fish.

(7) A small variation in excess base, equivalent to about 0-1% of the total calcium present, has been detected between the surface and bottom in summer. The result requires confirmation.

Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 18 , Issue 2 , January 1933 , pp. 729 - 753
Copyright
Copyright © Marine Biological Association of the United Kingdom 1933

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

REFERENCES

Adeney, W. E.; and Becker, H. G. 1918–20. The Determination of the Rate of Solution of Atmospheric Nitrogen and Oxygen by Water. Parts I–III. Scient. Proc. Roy. Dublin Soc., Vol. 15, pp. 385404, 609–628; Vol. 16, pp. 143–152.Google Scholar
Adeney, W. E., Leonard, A. G. G., and Richardson, A. 1922. On the Aeration of Quiescent Columns of Distilled Water and of Solutions of Sodium Chloride. Scient. Proc. Roy. Dublin Soc., Vol. 17, pp. 1928.Google Scholar
Adeney, W. E. 1926. On the Rate and Mechanism of Aeration of Water under Open Air Conditions. Scient. Proc. Roy. Dublin Soc., Vol. 18, pp. 211217.Google Scholar
Atkins, W. R. G. 1922, 1923, 1924. The Hydrogen Ion Concentration of Sea-water in its Relation to Photosynthetic Changes. Parts I–III. Journ. Mar. Biol. Assoc., N.S., Vol. 12, pp. 717771; Vol. 13, pp. 93–118, 437–446.CrossRefGoogle Scholar
Buch, K. 1928. Die pH-Bestimmung des Meerwassers. Havsforskningsinst. Skrift No. 53, pp. 30.Google Scholar
Buch, K. 1929 (1). Über den Einfluss der Temperatur auf die pH-Bestimmung des Meerwassers. Havsforskningsinst. Skrift No. 61, pp. 23.Google Scholar
Buch, K. 1929 (2). On the Determination of pH in Sea-water at Different Temperatures. Journ. du Conseil, Vol. 4, pp. 26280.CrossRefGoogle Scholar
Buch, K., Harvey, H. W., Wattenberg, H., and Grtpenberg, S. 1932. Über das Kohlensäuxesystem im Meerwasser. Conseil Int. p. l'Exploration de la Mer. Rapp. et Procès-verbaux, Vol. 79, pp. 70.Google Scholar
Fox, C. J. J. 1907. On the Coefficients of Absorption of the Atmospheric Gases in Sea-water and Distilled Water. Publ. de Circonstance, No. 41. Copenhagen.CrossRefGoogle Scholar
Ibañez, O. G. 1931. On the Colorimetric Determination of pH in Seawater. Journ. Mar. Biol. Assoc., N.S., Vol. 17, pp. 483488.CrossRefGoogle Scholar
Krogh, A. 1904. The Abnormal CO2-Percentage in the Air in Greenland and the General Relations between Atmospheric and Oceanic Carbonic Acid. Meddelelser om Gronland, Vol. 26, pp. 407434; cf. idem, Meddelelser om Gronland, Vol. 26, pp. 331–405.Google Scholar
Krümmel, O.Handbuch der Ozeanographie, Band I. Stuttgart, 1907, p. 315.Google Scholar
McClendon, J. F. 1917. The Standardisation of a New Colorimetric Method for the Determuiation of the Hydrogen Ion Concentration, CO2 Tension, and CO2 and O2 Content of Sea-water, etc. Journ. Biol. Chem., Vol. 30, pp. 265288.CrossRefGoogle Scholar
Wailes, . 1929. Plant Life in the Open Sea. Museum and Art Notes, Vancouver, Vol. 4, No. 1, p. 25.Google Scholar
Wattenberg, H. 1930. Über die Bestimmung der Alkalinität des Meerwassers. Über den Kalkgehalt des Ozeanwassers. I. Mitteilung. Ann. d. Hydrographie usw., Vol. 58, pp. 277282.Google Scholar
Wattenberg, H. 1931. Über den Kalkgehalt des Ozeanwassers. II. Mitteilung: Die Verteilung im Atlantischen Ozean. Ann. d. Hydrographie usw., Vol. 59, pp. 273277.Google Scholar
Williamson, R. V., and Mathews, J. H. 1924. Rate of Absorption and Equilibrium of Carbon Dioxide in Alkaline Solutions. Ind. Eng. Chem., Vol. 16, pp. 1157–61.CrossRefGoogle Scholar