Atomistic Simulation of Ceramic/Metal Interfaces: {222}MgO/Cu

R. Benedek; D.N. Seidman; L.H. Yang

doi:10.1017/S1431927697970252

Abstract

Abstract: Atomistic simulations were performed for the {222}MgO/Cu interface by local density functional theory (LDFT) methods, within the plane-wave-pseudopotential representation, and by (classical) molecular dynamics and statics. The electronic spectra obtained with LDFT calculations showed a localized interface state within the bulk MgO gap, approximately 1 eV above the MgO valence band edge. LDFT adhesive energy calculations, as a function of interface spacing and translations parallel to the interface, were employed to devise an interatomic potential suitable for large-scale atomistic simulation. The interface structure, which was obtained with molecular dynamics (and statics) calculations based on the resultant potential, exhibited a misfit dislocation network with trigonal symmetry, and no standoff dislocations.

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Atomistic Simulation of Ceramic/Metal Interfaces: {222}MgO/Cu

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