Atomic scale structure of ionic and semiconducting solid solutions

23 August 1993

journal article
Published by IOP Publishing in Journal of Physics: Condensed Matter

Vol. 5 (34B) , B37-B48
https://doi.org/10.1088/0953-8984/5/34b/007

Abstract

Experimental studies of the atomic scale structure of ionic and semiconducting solid solutions have shown that the bond-length mismatch is partially accommodated by microscopic lattice distortions and that the values of the nearest-neighbour bond lengths are intermediate between those of the corresponding pure compounds and the average Vegard value. Here the authors investigate theoretically the atomic scale structure of alloys using a generalized Born-Mayer model in the ionic case and an ab-initio pseudopotential approach for semiconductors. They also present results for the atomic scale structure of semiconductor heterojunctions and discuss how much interfacial and bulk strains can influence the electronic properties of the interface.

Keywords

SOLID SOLUTION

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