PARAMETERS AND VALIDITY OF FORCE-FIELD MODELS OF SILICON USING AB INITIO CALCULATIONS ON SMALL CLUSTERS.

A. Zur; T. C. McGill; W. A. Goddard

PARAMETERS AND VALIDITY OF FORCE-FIELD MODELS OF SILICON USING AB INITIO CALCULATIONS ON SMALL CLUSTERS.

A. Zur
, T. C. McGill
, W. A. Goddard

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Ab initio quantum mechanical calculations were performed on small silicon clusters to obtain their elastic constants. The elastic force constants of the clusters were then used to calculate the parameters of several force-field models, relating the elastic strain energy to atomic positions. These force-field models were, in turn, used to calculate the phonon band structure of bulk silicon. By comparing the ab initio phonon band structures with experimental results, we have obtained useful information regarding the validity of these force-field models, as well as their appropriate sets of parameters.

Original language	English
Title of host publication	Unknown Host Publication Title
Publisher	Metallurgical Soc of AIME
Pages	235-241
Number of pages	7
ISBN (Print)	0895204851
Publication status	Published - 1 Jan 1985
Externally published	Yes

Cite this

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title = "PARAMETERS AND VALIDITY OF FORCE-FIELD MODELS OF SILICON USING AB INITIO CALCULATIONS ON SMALL CLUSTERS.",

abstract = "Ab initio quantum mechanical calculations were performed on small silicon clusters to obtain their elastic constants. The elastic force constants of the clusters were then used to calculate the parameters of several force-field models, relating the elastic strain energy to atomic positions. These force-field models were, in turn, used to calculate the phonon band structure of bulk silicon. By comparing the ab initio phonon band structures with experimental results, we have obtained useful information regarding the validity of these force-field models, as well as their appropriate sets of parameters.",

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AU - McGill, T. C.

AU - Goddard, W. A.

PY - 1985/1/1

Y1 - 1985/1/1

N2 - Ab initio quantum mechanical calculations were performed on small silicon clusters to obtain their elastic constants. The elastic force constants of the clusters were then used to calculate the parameters of several force-field models, relating the elastic strain energy to atomic positions. These force-field models were, in turn, used to calculate the phonon band structure of bulk silicon. By comparing the ab initio phonon band structures with experimental results, we have obtained useful information regarding the validity of these force-field models, as well as their appropriate sets of parameters.

AB - Ab initio quantum mechanical calculations were performed on small silicon clusters to obtain their elastic constants. The elastic force constants of the clusters were then used to calculate the parameters of several force-field models, relating the elastic strain energy to atomic positions. These force-field models were, in turn, used to calculate the phonon band structure of bulk silicon. By comparing the ab initio phonon band structures with experimental results, we have obtained useful information regarding the validity of these force-field models, as well as their appropriate sets of parameters.

UR - https://www.scopus.com/pages/publications/0021788902

M3 - Conference contribution

AN - SCOPUS:0021788902

SN - 0895204851

SP - 235

EP - 241

BT - Unknown Host Publication Title

PB - Metallurgical Soc of AIME

ER -

PARAMETERS AND VALIDITY OF FORCE-FIELD MODELS OF SILICON USING AB INITIO CALCULATIONS ON SMALL CLUSTERS.

Abstract

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