Force constant and mass disorder in vibrational systems in the coherent-potential approximation

15 February 1974

journal article
research article
Published by American Physical Society (APS) in Physical Review B

Vol. 9 (4) , 1783-1791
https://doi.org/10.1103/physrevb.9.1783

Abstract

The coherent-potential approximation (CPA) for vibrational systems is extended to include force-constant changes as well as mass defects in alloys for which the force constants superimpose linearly. Such a model is correct at both the low- and high-concentration limits, and may be reasonable for broad concentration ranges in some real systems, for example, in diatomic alloys like mixed alkali halides. Results for one-dimensional systems with nearest-neighbor force constant and mass disorder have the same over-all agreement with exact results as was previously found for CPA calculations for mass defects only. Applications in three dimensions appear to be computationally feasible.

Keywords

This publication has 28 references indexed in Scilit:

Local modes in ${Al}_{0.1}$ ${Cu}_{0.9}$ and ${(N H_{4})}_{0.1}$ $K_{0.9}$ Cl in the coherent-potential approximation
Physical Review B, 1974
Impurity Phonon Modes in Ge-Si
Physical Review B, 1973
CPA reflectivity of mixed alkali halides
Solid State Communications, 1973
Densities of States of Paramagnetic Cu-Ni Alloys
Physical Review B, 1971
Band Structure of SiGe: Coherent-Potential Approximation
Physical Review B, 1970
Paramagnetic $Ni Cu$ Alloys: Electronic Density of States in the Coherent-Potential Approximation
Physical Review B, 1970
Contribution to the Theory of Disordered Alloys
Physical Review B, 1969
Single-Site Approximations in the Electronic Theory of Simple Binary Alloys
Physical Review B, 1968
Coherent-Potential Model of Substitutional Disordered Alloys
Physical Review B, 1967
Vibrational Properties of Imperfect Crystals with Large Defect Concentrations
Physical Review B, 1967