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Paper detail

Classical interaction potentials for diverse materials from ab initio data: a review of potfit

Force matching is an established technique to generate effective potentials for molecular dynamics simulations from first-principles data. This method has been implemented in the open source code potfit. Here, we present a review of the method and describe the main features of the code. Particular emphasis is placed on the features added since the initial release: interactions represented by analytical functions, differential evolution as optimization method, and a greatly extended set of interaction models. Beyond the initially present pair and embedded-atom method potentials, potfit can now also optimize angular dependent potentials, charge and dipolar interactions, and electron-temperature-dependent potentials. We demonstrate the functionality of these interaction models using three example systems: phonons in type I clathrates, fracture of α-alumina, and laser-irradiated silicon.

preprint2015arXivOpen access
Peter BrommerAlexander KiselevDaniel SchopfPhilipp BeckJohannes RothHans-Rainer Trebin
cond-mat.mtrl-sciphysics.comp-ph
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Peter BrommerAlexander KiselevDaniel SchopfPhilipp BeckJohannes RothHans-Rainer Trebin

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