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XV.—A Theoretical Atomic Distribution Curve for Liquid Argon at 90° K

Published online by Cambridge University Press:  15 September 2014

G. S. Rushbrooke
G. S. Rushbrooke
Affiliation:
University College, Dundee
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Extract

The radial distribution of the atoms (or molecules) of liquids, as of solids, can be found from X-ray scattering photographs (Zernike and Prins, 1927; Warren and Gingrich, 1934), and in this way many such distributions have been determined experimentally (Harvey, 1938, 1939; Gingrich, 1940; references in Coulson and Rushbrooke, 1939). The results are generally given as distribution curves showing p(r) or r2p(r) as a function of r, where 4πr2p(r)dr measures the probability that two arbitrarily selected atoms (or molecules) of the liquid are distant r to r + dr apart. Such distribution curves show a sequence of peaks—for ρ(r) these are usually of diminishing amplitude—and for atomic liquids successive peaks may conveniently be ascribed to successive co-ordination shells (of atoms) about any (arbitrarily selected) central atom. The position and precise shape of the peaks depends, of course, upon the temperature as well as the substance of the liquid.

Type
Proceedings
Information
Proceedings of the Royal Society of Edinburgh , Volume 60 , Issue 2 , 1940 , pp. 182 - 191
Copyright
Copyright © Royal Society of Edinburgh 1940

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References

References to Literature

Bernal, J. D., 1936. “An Attempt at a Molecular Theory of Liquid Structure,” Trans. Faraday Soc., vol. xxxiii, pp. 2740.Google Scholar
Bickley, W. G., 1939. “Formulæ for Numerical Integration,Math. Gaz., vol. xxiii, pp. 352359.CrossRefGoogle Scholar
Corner, J., 1939. “Zero-point Energy and Lattice Distances,Trans. Faraday Soc., vol. xxxv, pp. 711716.CrossRefGoogle Scholar
Coulson, C. A., and Rushbrooke, G. S., 1939. “On the Interpretation of Atomic Distribution Curves for Liquids,” Phys. Rev., vol. lvi, pp. 12161223.CrossRefGoogle Scholar
Fowler, R. H., 1936. Statistical Mechanics, p. 306, Cambridge.Google Scholar
Gingrich, N. S., 1940. “The Diffraction of X-rays by Liquid and Plastic Sulphur,” Journ. Chem. Phys., vol. viii, pp. 2932.CrossRefGoogle Scholar
Gingrich, N. S., and Wall, C. N., 1939. “The Structure of Liquid Potassium,” Phys. Rev., vol. lvi, pp. 336339.CrossRefGoogle Scholar
Harvey, G. G., 1938. “Fourier Analysis of Liquid Methyl Alcohol,Journ. Chem. Phys., vol. vi, pp. 111114.CrossRefGoogle Scholar
Harvey, G. G., 1939. “X-ray Diffraction in Liquid Ethyl Alcohol,Journ. Chem. Phys., vol. vii, pp. 878880.CrossRefGoogle Scholar
Herzfeld, K. F., 1937. “The Second Virial Coefficient of Argon,Phys. Rev., vol. lii, p. 374.CrossRefGoogle Scholar
Kirkwood, J. G., 1939. “Molecular Distribution in Liquids,Journ. Chem. Phys., vol. vii, pp. 919925.CrossRefGoogle Scholar
Lennard-Jones, J. E., and Devonshire, A. F., 1937. “Critical Phenomena in Gases—I,” Proc. Roy. Soc., A, vol. clxiii, pp. 5370.Google Scholar
Lennard-Jones, J. E., and Devonshire, A. F., 1938. “Critical Phenomena in Gases—II. Vapour Pressures and Boiling Points,” Proc. Roy. Soc., A, vol. clxv, pp. 111.Google Scholar
Mott, N. F., and Gurney, R. W., 1938. Reports on Progress in Physics, vol. v, pp. 4663, Physical Society of London.Google Scholar
Wall, C. N., 1938. “An Atomic Distribution Function for Liquid Sodium,” Phys. Rev., vol. liv, pp. 10621067.CrossRefGoogle Scholar
Warren, B. E., and Gingrich, N. S., 1934. “Fourier Analysis of X-ray Powder Patterns,” Phys. Rev., vol. xlvi, pp. 368372.CrossRefGoogle Scholar
Zernike, F., and Prins, J. A., 1927. “X-ray Diffraction in Liquids,Zeits. für Phys., vol. xli, pp. 184194.CrossRefGoogle Scholar