Hydrogen/silicon complexes in silicon from computational searches

Andrew J. Morris; Chris J. Pickard; R. J. Needs

doi:10.1103/PhysRevB.78.184102

Hydrogen/silicon complexes in silicon from computational searches

Andrew J. Morris, Chris J. Pickard, R. J. Needs

School of Physics and Astronomy

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

Abstract

Defects in crystalline silicon consisting of a silicon self-interstitial atom and one, two, three, or four hydrogen atoms are studied within density-functional theory (DFT). We search for low-energy defects by starting from an ensemble of structures in which the atomic positions in the defect region have been randomized. We then relax each structure to a minimum in the energy. We find a new defect consisting of a self-interstitial and one hydrogen atom (denoted by {I,H}) which has a higher symmetry and a lower energy than previously reported structures. We recover the (I, H-2} defect found in previous studies and confirm that it is the most stable such defect. Our best {I,H-3} defect has a slightly different structure and lower energy than the one previously reported, and our lowest-energy {I,H-4} defect is different to those of previous studies.

Original language	English
Number of pages	8
Journal	Physical Review. B, Condensed matter and materials physics
Volume	78
DOIs	https://doi.org/10.1103/PhysRevB.78.184102
Publication status	Published - Nov 2008

Keywords

MONTE-CARLO CALCULATIONS
CRYSTALLINE SILICON
SELF-INTERSTITIALS
BRILLOUIN-ZONE
DIFFUSION
PSEUDOPOTENTIALS
VIBRATIONS
GERMANIUM
POINTS

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10.1103/PhysRevB.78.184102

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title = "Hydrogen/silicon complexes in silicon from computational searches",

abstract = "Defects in crystalline silicon consisting of a silicon self-interstitial atom and one, two, three, or four hydrogen atoms are studied within density-functional theory (DFT). We search for low-energy defects by starting from an ensemble of structures in which the atomic positions in the defect region have been randomized. We then relax each structure to a minimum in the energy. We find a new defect consisting of a self-interstitial and one hydrogen atom (denoted by {I,H}) which has a higher symmetry and a lower energy than previously reported structures. We recover the (I, H-2} defect found in previous studies and confirm that it is the most stable such defect. Our best {I,H-3} defect has a slightly different structure and lower energy than the one previously reported, and our lowest-energy {I,H-4} defect is different to those of previous studies.",

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author = "Morris, {Andrew J.} and Pickard, {Chris J.} and Needs, {R. J.}",

year = "2008",

month = nov,

doi = "10.1103/PhysRevB.78.184102",

language = "English",

volume = "78",

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T1 - Hydrogen/silicon complexes in silicon from computational searches

AU - Morris, Andrew J.

AU - Pickard, Chris J.

AU - Needs, R. J.

PY - 2008/11

Y1 - 2008/11

N2 - Defects in crystalline silicon consisting of a silicon self-interstitial atom and one, two, three, or four hydrogen atoms are studied within density-functional theory (DFT). We search for low-energy defects by starting from an ensemble of structures in which the atomic positions in the defect region have been randomized. We then relax each structure to a minimum in the energy. We find a new defect consisting of a self-interstitial and one hydrogen atom (denoted by {I,H}) which has a higher symmetry and a lower energy than previously reported structures. We recover the (I, H-2} defect found in previous studies and confirm that it is the most stable such defect. Our best {I,H-3} defect has a slightly different structure and lower energy than the one previously reported, and our lowest-energy {I,H-4} defect is different to those of previous studies.

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KW - MONTE-CARLO CALCULATIONS

KW - CRYSTALLINE SILICON

KW - SELF-INTERSTITIALS

KW - BRILLOUIN-ZONE

KW - DIFFUSION

KW - PSEUDOPOTENTIALS

KW - VIBRATIONS

KW - GERMANIUM

KW - POINTS

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DO - 10.1103/PhysRevB.78.184102

M3 - Article

SN - 1098-0121

VL - 78

JO - Physical Review. B, Condensed matter and materials physics

JF - Physical Review. B, Condensed matter and materials physics

ER -

Hydrogen/silicon complexes in silicon from computational searches

Abstract

Keywords

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