Empirical interatomic potential for the mechanical, vibrational and thermodynamic properties of semiconductors

U Monteverde; M A Migliorato; D Powell

doi:012015 10.1088/1742-6596/367/1/012015

Empirical interatomic potential for the mechanical, vibrational and thermodynamic properties of semiconductors

U Monteverde, M A Migliorato, D Powell

Research output: Chapter in Book/Conference proceeding › Chapter

Abstract

Empirical models are widely used to simulate large atomic structures where instead ab initio methods are not practical because of computational limitations. However models such as Tersoff potential [8], [9], Valence Force Field [13], [14] or Stillinger- Weber potential [15] have some restrictions in correctly predicting simultaneously both elastic and vibrational properties of the crystals [18]. Thus, extension of the functional form of the potentials by including further atomic interactions [20] [21] compared to the simple 2- and 3-body terms, is required. An empirical interatomic potential is proposed which represents a substantial improvement of the Tersoff potential for semiconductors modelling. The new model includes multi-bond interactions and the volume dependency by considering the tetrahedron distortions of the covalent crystal.

Original language	English
Title of host publication	3rd Workshop on Theory, Modelling and Computational Methods for Semiconductors
Volume	367
ISBN (Electronic)	1742-6588
DOIs	https://doi.org/012015 10.1088/1742-6596/367/1/012015
Publication status	Published - 2012

Publication series

Name	Journal of Physics Conference Series

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012015 10.1088/1742-6596/367/1/012015

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title = "Empirical interatomic potential for the mechanical, vibrational and thermodynamic properties of semiconductors",

abstract = "Empirical models are widely used to simulate large atomic structures where instead ab initio methods are not practical because of computational limitations. However models such as Tersoff potential [8], [9], Valence Force Field [13], [14] or Stillinger- Weber potential [15] have some restrictions in correctly predicting simultaneously both elastic and vibrational properties of the crystals [18]. Thus, extension of the functional form of the potentials by including further atomic interactions [20] [21] compared to the simple 2- and 3-body terms, is required. An empirical interatomic potential is proposed which represents a substantial improvement of the Tersoff potential for semiconductors modelling. The new model includes multi-bond interactions and the volume dependency by considering the tetrahedron distortions of the covalent crystal.",

author = "U Monteverde and Migliorato, {M A} and D Powell",

note = "Times Cited: 0 TMCSIII 3rd Workshop on Theory, Modelling and Computational Methods for Semiconductor Materials and Nanostructures (TMCS) JAN 18-20, 2012 Univ Leeds, Sch Elect & Elect Engn, Leeds, ENGLAND Inst Phys (Computat Phys grp & Semiconductor Phys grp); QuantumWise",

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doi = "012015 10.1088/1742-6596/367/1/012015",

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T1 - Empirical interatomic potential for the mechanical, vibrational and thermodynamic properties of semiconductors

AU - Monteverde, U

AU - Migliorato, M A

AU - Powell, D

N1 - Times Cited: 0 TMCSIII 3rd Workshop on Theory, Modelling and Computational Methods for Semiconductor Materials and Nanostructures (TMCS) JAN 18-20, 2012 Univ Leeds, Sch Elect & Elect Engn, Leeds, ENGLAND Inst Phys (Computat Phys grp & Semiconductor Phys grp); QuantumWise

PY - 2012

Y1 - 2012

N2 - Empirical models are widely used to simulate large atomic structures where instead ab initio methods are not practical because of computational limitations. However models such as Tersoff potential [8], [9], Valence Force Field [13], [14] or Stillinger- Weber potential [15] have some restrictions in correctly predicting simultaneously both elastic and vibrational properties of the crystals [18]. Thus, extension of the functional form of the potentials by including further atomic interactions [20] [21] compared to the simple 2- and 3-body terms, is required. An empirical interatomic potential is proposed which represents a substantial improvement of the Tersoff potential for semiconductors modelling. The new model includes multi-bond interactions and the volume dependency by considering the tetrahedron distortions of the covalent crystal.

AB - Empirical models are widely used to simulate large atomic structures where instead ab initio methods are not practical because of computational limitations. However models such as Tersoff potential [8], [9], Valence Force Field [13], [14] or Stillinger- Weber potential [15] have some restrictions in correctly predicting simultaneously both elastic and vibrational properties of the crystals [18]. Thus, extension of the functional form of the potentials by including further atomic interactions [20] [21] compared to the simple 2- and 3-body terms, is required. An empirical interatomic potential is proposed which represents a substantial improvement of the Tersoff potential for semiconductors modelling. The new model includes multi-bond interactions and the volume dependency by considering the tetrahedron distortions of the covalent crystal.

U2 - 012015 10.1088/1742-6596/367/1/012015

DO - 012015 10.1088/1742-6596/367/1/012015

M3 - Chapter

VL - 367

T3 - Journal of Physics Conference Series

BT - 3rd Workshop on Theory, Modelling and Computational Methods for Semiconductors

ER -

Empirical interatomic potential for the mechanical, vibrational and thermodynamic properties of semiconductors

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