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Philosophical Magazine A Volume 54, 1986 - Issue 6
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Original Articles

Computer simulation of twin boundaries in the h.c.p. metals

A. Serra Departament de Fisica, ETSI Camins, Universitat Politénica de Catalunya, Jordi Girona Salgado 31, Barcelona, 08034, Spain
&
D. J. Bacon Department of Materials Science and Engineering, The University of Liverpool, Liverpool, L69 3BX, England
Pages 793-804 | Received 16 Apr 1986, Accepted 13 May 1986, Published online: 04 Oct 2006
 
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Abstract

The energy and atomic structure of {1121}, {1122) and {1012} twin boundaries in the hexagonal-close-packed (h.c.p.) metals have been investigated using computer simulation. Three distinctly different interatomic potential functions have been used in either equilibrium or non-equilibrium form. It is predicted that only one form of boundary can occur for {1121} and {1012} twins, but several interfaces may exist for (1122} twins. The stable boundaries are, with one exception, associated with one or both of the symmetry operations of reflection and 2-fold rotation defined in the conventional theory of twinning. The good agreement between the results for all six model crystals suggests that the structures found here have general relevance to twin boundaries in real h.c.p. metals.

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