Quantum mechanical description of displacement damage formation

M. J. Beck; R. Hatcher; R. D. Schrimpf; D. M. Fleetwood; S. T. Pantelides

doi:10.1109/TNS.2007.910231

Quantum mechanical description of displacement damage formation

M. J. Beck
, R. Hatcher
, R. D. Schrimpf
, D. M. Fleetwood
, S. T. Pantelides

Producción científica: Article › revisión exhaustiva

21 Citas (Scopus)

Resumen

Atomic-scale processes during displacement damage formation have been previously studied using molecular dynamics (MD) calculations and empirical potentials. Low-energy displacements < keV) are characterized by a high cross-section for producing secondary knock-on atoms and damage clusters, and determine the threshold displacement energy (an important parameter in NIEL calculations). Here we report first-principles, parameter-free quantum mechanical calculations of the dynamics of low-energy displacement damage events. We find that isolated defects formed by direct displacements result from damage events of ≤100 eV. For higher energy events, the initial defect profile, which subsequently undergoes thermal annealing to give rise to a final stable defect profile, is the result of the relaxation and recrystallization of an appreciable volume of significantly disordered and locally heated crystal surrounding the primary knock-on atom displacement trajectory.

Idioma original	English
Páginas (desde-hasta)	1906-1912
Número de páginas	7
Publicación	IEEE Transactions on Nuclear Science
Volumen	54
N.º	6
DOI	https://doi.org/10.1109/TNS.2007.910231
Estado	Published - dic 2007

Nota bibliográfica

Funding Information:
Manuscript received July 21, 2007; revised September 5, 2007. This work was supported by the Air Force Office of Scientific Research (AFOSR) MURI program. The calculations were conducted at the U.S. Army Research Laboratory MSRC.

Financiación

Manuscript received July 21, 2007; revised September 5, 2007. This work was supported by the Air Force Office of Scientific Research (AFOSR) MURI program. The calculations were conducted at the U.S. Army Research Laboratory MSRC.

Financiadores
Air Force Office of Scientific Research, United States Air Force

ASJC Scopus subject areas

Nuclear and High Energy Physics
Nuclear Energy and Engineering
Electrical and Electronic Engineering

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10.1109/TNS.2007.910231

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title = "Quantum mechanical description of displacement damage formation",

abstract = "Atomic-scale processes during displacement damage formation have been previously studied using molecular dynamics (MD) calculations and empirical potentials. Low-energy displacements < keV) are characterized by a high cross-section for producing secondary knock-on atoms and damage clusters, and determine the threshold displacement energy (an important parameter in NIEL calculations). Here we report first-principles, parameter-free quantum mechanical calculations of the dynamics of low-energy displacement damage events. We find that isolated defects formed by direct displacements result from damage events of ≤100 eV. For higher energy events, the initial defect profile, which subsequently undergoes thermal annealing to give rise to a final stable defect profile, is the result of the relaxation and recrystallization of an appreciable volume of significantly disordered and locally heated crystal surrounding the primary knock-on atom displacement trajectory.",

keywords = "Density functional theory, Displacement damage, Local melting",

author = "Beck, \{M. J.\} and R. Hatcher and Schrimpf, \{R. D.\} and Fleetwood, \{D. M.\} and Pantelides, \{S. T.\}",

note = "Funding Information: Manuscript received July 21, 2007; revised September 5, 2007. This work was supported by the Air Force Office of Scientific Research (AFOSR) MURI program. The calculations were conducted at the U.S. Army Research Laboratory MSRC.",

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language = "English",

volume = "54",

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AU - Beck, M. J.

AU - Hatcher, R.

AU - Schrimpf, R. D.

AU - Fleetwood, D. M.

AU - Pantelides, S. T.

N1 - Funding Information: Manuscript received July 21, 2007; revised September 5, 2007. This work was supported by the Air Force Office of Scientific Research (AFOSR) MURI program. The calculations were conducted at the U.S. Army Research Laboratory MSRC.

PY - 2007/12

Y1 - 2007/12

N2 - Atomic-scale processes during displacement damage formation have been previously studied using molecular dynamics (MD) calculations and empirical potentials. Low-energy displacements < keV) are characterized by a high cross-section for producing secondary knock-on atoms and damage clusters, and determine the threshold displacement energy (an important parameter in NIEL calculations). Here we report first-principles, parameter-free quantum mechanical calculations of the dynamics of low-energy displacement damage events. We find that isolated defects formed by direct displacements result from damage events of ≤100 eV. For higher energy events, the initial defect profile, which subsequently undergoes thermal annealing to give rise to a final stable defect profile, is the result of the relaxation and recrystallization of an appreciable volume of significantly disordered and locally heated crystal surrounding the primary knock-on atom displacement trajectory.

AB - Atomic-scale processes during displacement damage formation have been previously studied using molecular dynamics (MD) calculations and empirical potentials. Low-energy displacements < keV) are characterized by a high cross-section for producing secondary knock-on atoms and damage clusters, and determine the threshold displacement energy (an important parameter in NIEL calculations). Here we report first-principles, parameter-free quantum mechanical calculations of the dynamics of low-energy displacement damage events. We find that isolated defects formed by direct displacements result from damage events of ≤100 eV. For higher energy events, the initial defect profile, which subsequently undergoes thermal annealing to give rise to a final stable defect profile, is the result of the relaxation and recrystallization of an appreciable volume of significantly disordered and locally heated crystal surrounding the primary knock-on atom displacement trajectory.

KW - Density functional theory

KW - Displacement damage

KW - Local melting

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U2 - 10.1109/TNS.2007.910231

DO - 10.1109/TNS.2007.910231

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SN - 0018-9499

VL - 54

SP - 1906

EP - 1912

JO - IEEE Transactions on Nuclear Science

JF - IEEE Transactions on Nuclear Science

IS - 6

ER -

Quantum mechanical description of displacement damage formation

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Financiación

ASJC Scopus subject areas

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