Quantum chemical simulations of hole self-trapping in corundum

P. W.M. Jacobs; E. A. Kotomin; A. Stashans; E. V. Stefanovich; I. Tale

doi:10.1088/0953-8984/4/37/001

Quantum chemical simulations of hole self-trapping in corundum

P. W.M. Jacobs^*
, E. A. Kotomin
, A. Stashans
, E. V. Stefanovich
, I. Tale

^*Corresponding author for this work

Western University

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

51 Citations (Scopus)

Abstract

Microscopic quantum chemical calculations and simulations based on atom-atom potentials have been undertaken for hole self-trapping in pure corundum ( alpha -Al₂O₃) crystals. A comparison of different modes of ionic relaxation during hole trapping has shown that the inward Jahn-Teller 40% displacement of two O ions accompanied by the 20% outward displacement of the two nearest Al ions is energetically the most favourable. Eighty per cent of the hole density is concentrated on these two O ions, thus confirming that a small-radius two-site polaron model similar to that for alkali halides (the V_K centre), is applicable here. The calculated absorption energy of the STH (2.9 eV) is close to that observed experimentally.

Original language	English
Article number	001
Pages (from-to)	7531-7544
Number of pages	14
Journal	Journal of Physics Condensed Matter
Volume	4
Issue number	37
DOIs	https://doi.org/10.1088/0953-8984/4/37/001
Publication status	Published - 1992
Externally published	Yes

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title = "Quantum chemical simulations of hole self-trapping in corundum",

abstract = "Microscopic quantum chemical calculations and simulations based on atom-atom potentials have been undertaken for hole self-trapping in pure corundum ( alpha -Al2O3) crystals. A comparison of different modes of ionic relaxation during hole trapping has shown that the inward Jahn-Teller 40\% displacement of two O ions accompanied by the 20\% outward displacement of the two nearest Al ions is energetically the most favourable. Eighty per cent of the hole density is concentrated on these two O ions, thus confirming that a small-radius two-site polaron model similar to that for alkali halides (the VK centre), is applicable here. The calculated absorption energy of the STH (2.9 eV) is close to that observed experimentally.",

author = "Jacobs, \{P. W.M.\} and Kotomin, \{E. A.\} and A. Stashans and Stefanovich, \{E. V.\} and I. Tale",

year = "1992",

doi = "10.1088/0953-8984/4/37/001",

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T1 - Quantum chemical simulations of hole self-trapping in corundum

AU - Jacobs, P. W.M.

AU - Kotomin, E. A.

AU - Stashans, A.

AU - Stefanovich, E. V.

AU - Tale, I.

PY - 1992

Y1 - 1992

N2 - Microscopic quantum chemical calculations and simulations based on atom-atom potentials have been undertaken for hole self-trapping in pure corundum ( alpha -Al2O3) crystals. A comparison of different modes of ionic relaxation during hole trapping has shown that the inward Jahn-Teller 40% displacement of two O ions accompanied by the 20% outward displacement of the two nearest Al ions is energetically the most favourable. Eighty per cent of the hole density is concentrated on these two O ions, thus confirming that a small-radius two-site polaron model similar to that for alkali halides (the VK centre), is applicable here. The calculated absorption energy of the STH (2.9 eV) is close to that observed experimentally.

AB - Microscopic quantum chemical calculations and simulations based on atom-atom potentials have been undertaken for hole self-trapping in pure corundum ( alpha -Al2O3) crystals. A comparison of different modes of ionic relaxation during hole trapping has shown that the inward Jahn-Teller 40% displacement of two O ions accompanied by the 20% outward displacement of the two nearest Al ions is energetically the most favourable. Eighty per cent of the hole density is concentrated on these two O ions, thus confirming that a small-radius two-site polaron model similar to that for alkali halides (the VK centre), is applicable here. The calculated absorption energy of the STH (2.9 eV) is close to that observed experimentally.

UR - https://www.scopus.com/pages/publications/36149032674

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DO - 10.1088/0953-8984/4/37/001

M3 - Article

AN - SCOPUS:36149032674

SN - 0953-8984

VL - 4

SP - 7531

EP - 7544

JO - Journal of Physics Condensed Matter

JF - Journal of Physics Condensed Matter

IS - 37

M1 - 001

ER -

Quantum chemical simulations of hole self-trapping in corundum

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