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Physical Factors on the Sandy Beach. Part II. Chemical Changes—Carbon Dioxide Concentration and Sulphides

Published online by Cambridge University Press:  11 May 2009

J. Ronald Bruce
J. Ronald Bruce
Affiliation:
Marine Biological Station, Port Erin.
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Summary

The presence of living organisms and their metabolic products introduce a further series of biochemical factors into the physical conditions of life on the sandy beach.

The gaseous exchanges of animals and plants lead to changes in the pH of the interstitial waters of the beach, but the calcareous matter associated with the sand acts as an alkali-reserve, preventing undue rise of acidity, and incidentally widening the potential range of carbonassimilation of the surface flora.

Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 15 , Issue 2 , April 1928 , pp. 553 - 565
Copyright
Copyright © Marine Biological Association of the United Kingdom 1928

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References

REFERENCES

N., Andrussow (1897). La Mer Noire. 7me Cong. Géol. Internat., Guide des Exc.Google Scholar
Bruce, J. R. (1924). A pH Method for Determining the Carbon Dioxide Exchanges of Marine, Brackish Water, and Freshwater Organisms. Brit. Journ. Exp. Biol., 2, 5764.CrossRefGoogle Scholar
Bruce, J. R. (1928). Physical Factors on the Sandy Beach, Part I, Journ. Mar. Biol. Assoc,. N.S., 15, 535552.CrossRefGoogle Scholar
Buchanan, J. Y. (1891). On the Occurrence of Sulphur in Marine Muds, etc. Proc. Roy. Soc, Edin., 18, 1739.CrossRefGoogle Scholar
Collip, J. B. (1920). Studies on Molluscan Celomic Fluid. Journ. Biol. Chem., 45, 2349.CrossRefGoogle Scholar
P., Danilčenko, and N., Čigirin (1926). Sur l'Origine de l'Hydrosulfure dans la Mer Noire. Trav. du lab. et de la Stat. Biol. de Sebastopol, Ser. ii, No. 10, 141191.Google Scholar
D., Ellis (1924). An Investigation into the Structure and Life-History of the Sulphur Bacteria (I). Proc. Roy. Soc, Edin., 44, ii, 153167.Google Scholar
D., Ellis (1925). An Investigation into the Cause of the Blackening of the Sand in Parts of the Clyde Estuary. Journ. Roy. Tech. Coll., Glasgow (1925), 144156.Google Scholar
Fox, C. J. J. (1905). On the Determination of the Atmospheric Gases Dissolved in Sea-Water. Cons. Intern. Explor. Mer, Publ. de Circ. 21.CrossRefGoogle Scholar
J., Johnstone (1921). On Black Littoral Sands in Lancashire. 29th Ann. Rept. (for 1920), Lancs., Sea-Fish. Lab., 106–109.Google Scholar
B., Lewy (1846). Recherches sur la Composition des Gaz que l'Eau de Mer tient en Dissolution dans les differents moments de la journée. Ann. Chim. et Phys., iii, 17, 523.Google Scholar
W., Omelianski (19041906). Der Kreislauf des Schwefels, in F. Lafar's “Technische Mykologie,” Bd. 3.Google Scholar