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Diffraction Studies of Liquids

  • J. E. Enderby
Part of the Physics of Solids and Liquids book series (PSLI)

Abstract

Simple liquids are those for which the intermolecular potential-energy function Φ(r 1? r 2,..., r N ) has the special form given by
$$\Phi \left( {{r_1},{r_2}, \ldots ,{r_N}} \right) = \sum\limits_{i < j} {\Phi \left( {{r_k},{r_j}} \right)} $$
(1.1.1)
where r k is the position vector of the kth atom or ion in the liquid, N is the total number of atoms, and Φ is the so-called pair potential. We also assume that Φ is spherically symmetric, i.e., it is a function of \(\left| r \right| = \left| {{r_k} - {r_j}} \right|\) . For a simple mixture composed of, say, a and b atoms, the interactions are characterized by three pair potentials, each spherically symmetric, given by Φ aa (r), Φ bb (r)? and Φ ab (r)? There is a considerable body of evidence which suggests that Φ for the liquid form of the rare gases (Ar, Kr, Ne, and Xe) approximates very closely a sum of spherically symmetric pair potentials. An example of the potential Φ used for liquid rare gases is given in Figure 1.1. More surprisingly, a model based on pair potentials can also be justified for liquid nontransition metals like Na and Al. In these cases, the form of Φ is not so well defined, but the general features presented in Figure 1.1 do not probably involve a serious error. A review of the usefulness of pair potentials for metallic systems lies outside the scope of this treatment; the reader is referred to the book by Faber(1) and to the references cited therein. Pair potentials are also very useful in molten salts. This topic has been revewed by Sangster and Dixon.(2)

Keywords

Molten Salt Radial Distribution Function Pair Potential Pair Correlation Function Amorphous Solid 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

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Copyright information

© Springer Science+Business Media New York 1985

Authors and Affiliations

  • J. E. Enderby
    • 1
  1. 1.H. H. Wills Physics LaboratoryUniversity of Bristol, Royal FortBristolEngland

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