Open AccessBond-order potential for simulations of extended defects in tungsten
Author(s) -
Matous Mrovec,
Roman Gröger,
Aimee Gotway Bailey,
D. Nguyen-Manh,
Christian Elsässer,
V. Vítek
Publication year - 2007
Publication title -
physical review b
Language(s) - English
Resource type - Journals
eISSN - 1538-4489
pISSN - 1098-0121
DOI - 10.1103/physrevb.75.104119
Subject(s) - materials science , tungsten , interatomic potential , bond order , covalent bond , tight binding , hierarchy , space (punctuation) , transition metal , chemical physics , atomic units , molecular dynamics , statistical physics , bond length , molecular physics , electronic structure , condensed matter physics , computational chemistry , physics , chemistry , computer science , quantum mechanics , molecule , market economy , biochemistry , economics , metallurgy , catalysis , operating system
We present a bond-order potential (BOP) for the bcc transition metal tungsten. The bond-order potentials are a real-space semiempirical scheme for the description of interatomic interactions based on the tight-binding approximation. In the hierarchy of atomic-scale-modeling methods the BOPs thus provide a direct bridge between electronic-structure and atomistic techniques. Two variants of the BOP were constructed and extensively tested against accurate first-principles methods in order to assess the potentials' reliability and applicability. A comparison of the BOP with a central-force potential is used to demonstrate that a correct description of directional mixed covalent and metallic bonds is crucial for a successful and fully transferable model. The potentials are applied in studies of low-index surfaces, symmetrical tilt grain boundaries, and dislocations
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