Two-band second moment model and an interatomic potential for caesium

A. Chen; A. Chen; A.K. MacMahan; B.B. Karki; C. Domain; E. Smargiassi; F. Ducastelle; G.J. Ackland; G.J. Ackland; G.J. Ackland; Graeme J. Ackland; H.T. Hall; J. Wang; J. Xie; K. Kadau; K. Takemura; M.I. McMahon; M.M. Abd-Elmeguid; M.S. Daw; M.W. Finnis; P. Hohenberg; P.M. Marcus; R. Boehler; R. Feynman; S.J. Clark; S.W. Han; Stewart K. Reed; U. Pinsook; U. Pinsook

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Two-band second moment model and an interatomic potential for caesium

Authors: A. Chen
A. Chen
A.K. MacMahan
B.B. Karki
C. Domain
E. Smargiassi
F. Ducastelle
G.J. Ackland
G.J. Ackland
G.J. Ackland
Graeme J. Ackland
H.T. Hall
J. Wang
J. Xie
K. Kadau
K. Takemura
M.I. McMahon
M.M. Abd-Elmeguid
M.S. Daw
M.W. Finnis
P. Hohenberg
P.M. Marcus
R. Boehler
R. Feynman
S.J. Clark
S.W. Han
Stewart K. Reed
U. Pinsook
U. Pinsook
Publication date: 9 December 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

A semi-empirical formalism is presented for deriving interatomic potentials for materials such as caesium or cerium which exhibit volume collapse phase transitions. It is based on the Finnis-Sinclair second moment tight binding approach, but incorporates two independent bands on each atom. The potential is cast in a form suitable for large-scale molecular dynamics, the computational cost being the evaluation of short ranged pair potentials. Parameters for a model potential for caesium are derived and tested

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