Saddle point for oxygen reorientation in the vicinity of a silicon vacancy

L. Dobaczewski; O. Andersen; L. Rubaldo; K. Gościński; V. P. Markevich; A. R. Peaker; K. Bonde Nielsen

doi:10.1103/PhysRevB.67.195204

Saddle point for oxygen reorientation in the vicinity of a silicon vacancy

L. Dobaczewski, O. Andersen, L. Rubaldo, K. Gościński, V. P. Markevich, A. R. Peaker, K. Bonde Nielsen

Research output: Contribution to journal › Article › peer-review

Abstract

A piezospectroscopic analysis of the vacancy-oxygen complex in silicon has enabled us to demonstrate that this defect in the unstable configuration of the saddle point on the reconfiguration trajectory has a trigonal symmetry. This unstable defect configuration may be considered as the precursor for an oxygen diffusion process where the migrating oxygen atom is accompanied by a vacancy. The trigonal saddle point configuration results in a strong electrical polarization of the pair which can aid the jumping to a neighboring unit cell. This scenario is very plausible to explain how vacancies can drag oxygen atoms through the crystal to form larger oxygen aggregates.

Original language	English
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	67
Issue number	19
DOIs	https://doi.org/10.1103/PhysRevB.67.195204
Publication status	Published - 22 May 2003

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abstract = "A piezospectroscopic analysis of the vacancy-oxygen complex in silicon has enabled us to demonstrate that this defect in the unstable configuration of the saddle point on the reconfiguration trajectory has a trigonal symmetry. This unstable defect configuration may be considered as the precursor for an oxygen diffusion process where the migrating oxygen atom is accompanied by a vacancy. The trigonal saddle point configuration results in a strong electrical polarization of the pair which can aid the jumping to a neighboring unit cell. This scenario is very plausible to explain how vacancies can drag oxygen atoms through the crystal to form larger oxygen aggregates.",

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AU - Dobaczewski, L.

AU - Andersen, O.

AU - Rubaldo, L.

AU - Gościński, K.

AU - Markevich, V. P.

AU - Peaker, A. R.

AU - Bonde Nielsen, K.

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AB - A piezospectroscopic analysis of the vacancy-oxygen complex in silicon has enabled us to demonstrate that this defect in the unstable configuration of the saddle point on the reconfiguration trajectory has a trigonal symmetry. This unstable defect configuration may be considered as the precursor for an oxygen diffusion process where the migrating oxygen atom is accompanied by a vacancy. The trigonal saddle point configuration results in a strong electrical polarization of the pair which can aid the jumping to a neighboring unit cell. This scenario is very plausible to explain how vacancies can drag oxygen atoms through the crystal to form larger oxygen aggregates.

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VL - 67

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

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ER -

Saddle point for oxygen reorientation in the vicinity of a silicon vacancy

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