Mechanism of vacancy formation induced by hydrogen in tungsten

Yi Nan Liu; T. Ahlgren; L. Bukonte; K. Nordlund; Xiaolin Shu; Yi Yu; Xiao Chun Li; Guang Hong Lu

doi:10.1063/1.4849775

Mechanism of vacancy formation induced by hydrogen in tungsten

Yi Nan Liu
, T. Ahlgren
, L. Bukonte
, K. Nordlund
, Xiaolin Shu
, Yi Yu
, Xiao Chun Li
, Guang Hong Lu

School of Physics

Beihang University
University of Helsinki
CAS - Institute of Plasma Physics

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

49 Scopus citations

Abstract

We report a hydrogen induced vacancy formation mechanism in tungsten based on classical molecular dynamics simulations. We demonstrate the vacancy formation in tungsten due to the presence of hydrogen associated directly with a stable hexagonal self-interstitial cluster as well as a linear crowdion. The stability of different self-interstitial structures has been further studied and it is particularly shown that hydrogen plays a crucial role in determining the configuration of SIAs, in which the hexagonal cluster structure is preferred. Energetic analysis has been carried out to prove that the formation of SIA clusters facilitates the formation of vacancies. Such a mechanism contributes to the understanding of the early stage of the hydrogen blistering in tungsten under a fusion reactor environment.

Original language	English
Article number	122111
Journal	AIP Advances
Volume	3
Issue number	12
DOIs	https://doi.org/10.1063/1.4849775
State	Published - Dec 2013

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title = "Mechanism of vacancy formation induced by hydrogen in tungsten",

abstract = "We report a hydrogen induced vacancy formation mechanism in tungsten based on classical molecular dynamics simulations. We demonstrate the vacancy formation in tungsten due to the presence of hydrogen associated directly with a stable hexagonal self-interstitial cluster as well as a linear crowdion. The stability of different self-interstitial structures has been further studied and it is particularly shown that hydrogen plays a crucial role in determining the configuration of SIAs, in which the hexagonal cluster structure is preferred. Energetic analysis has been carried out to prove that the formation of SIA clusters facilitates the formation of vacancies. Such a mechanism contributes to the understanding of the early stage of the hydrogen blistering in tungsten under a fusion reactor environment.",

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T1 - Mechanism of vacancy formation induced by hydrogen in tungsten

AU - Liu, Yi Nan

AU - Ahlgren, T.

AU - Bukonte, L.

AU - Nordlund, K.

AU - Shu, Xiaolin

AU - Yu, Yi

AU - Li, Xiao Chun

AU - Lu, Guang Hong

PY - 2013/12

Y1 - 2013/12

N2 - We report a hydrogen induced vacancy formation mechanism in tungsten based on classical molecular dynamics simulations. We demonstrate the vacancy formation in tungsten due to the presence of hydrogen associated directly with a stable hexagonal self-interstitial cluster as well as a linear crowdion. The stability of different self-interstitial structures has been further studied and it is particularly shown that hydrogen plays a crucial role in determining the configuration of SIAs, in which the hexagonal cluster structure is preferred. Energetic analysis has been carried out to prove that the formation of SIA clusters facilitates the formation of vacancies. Such a mechanism contributes to the understanding of the early stage of the hydrogen blistering in tungsten under a fusion reactor environment.

AB - We report a hydrogen induced vacancy formation mechanism in tungsten based on classical molecular dynamics simulations. We demonstrate the vacancy formation in tungsten due to the presence of hydrogen associated directly with a stable hexagonal self-interstitial cluster as well as a linear crowdion. The stability of different self-interstitial structures has been further studied and it is particularly shown that hydrogen plays a crucial role in determining the configuration of SIAs, in which the hexagonal cluster structure is preferred. Energetic analysis has been carried out to prove that the formation of SIA clusters facilitates the formation of vacancies. Such a mechanism contributes to the understanding of the early stage of the hydrogen blistering in tungsten under a fusion reactor environment.

UR - https://www.scopus.com/pages/publications/84891502823

U2 - 10.1063/1.4849775

DO - 10.1063/1.4849775

M3 - 文章

AN - SCOPUS:84891502823

SN - 2158-3226

VL - 3

JO - AIP Advances

JF - AIP Advances

IS - 12

M1 - 122111

ER -

Mechanism of vacancy formation induced by hydrogen in tungsten

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