Atomistic simulation of hydrogen diffusion at tilt grain boundaries in vanadium

Jae Hyeok Shim; Won Seok Ko; Jin Yoo Suh; Young Su Lee; Byeong Joo Lee

doi:10.1007/s12540-013-6012-0

Atomistic simulation of hydrogen diffusion at tilt grain boundaries in vanadium

Jae Hyeok Shim, Won Seok Ko, Jin Yoo Suh, Young Su Lee, Byeong Joo Lee

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

12 Scopus citations

Abstract

Molecular dynamics simulations of hydrogen diffusion at Σ3 and Σ5 tilt grain boundaries in bcc vanadium (V) have been performed based on modified embedded-atom method interatomic potentials. The calculated diffusivity at the grain boundaries is lower than the calculated bulk diffusivity in a temperature range between 473 and 1473 K, although the difference between the grain boundary and bulk diffusivities decreases with increasing temperature. Compared with that of the other directions, the mean square displacement of an interstitial hydrogen atom at the Σ3 boundary is relatively small in the direction normal to the boundary, leading to two dimensional motion. Molecular statics simulations show that there is strong attraction between the hydrogen atom and these grain boundaries in V, which implies that the role of grain boundaries is to act as trap sites rather than to provide fast diffusion paths of hydrogen atoms in V.

Original language	English
Pages (from-to)	1221-1225
Number of pages	5
Journal	Metals and Materials International
Volume	19
Issue number	6
DOIs	https://doi.org/10.1007/s12540-013-6012-0
State	Published - Nov 2013
Externally published	Yes

Keywords

computer simulation
diffusion
grain boundary
hydrogen
metals

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10.1007/s12540-013-6012-0

Cite this

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title = "Atomistic simulation of hydrogen diffusion at tilt grain boundaries in vanadium",

abstract = "Molecular dynamics simulations of hydrogen diffusion at Σ3 and Σ5 tilt grain boundaries in bcc vanadium (V) have been performed based on modified embedded-atom method interatomic potentials. The calculated diffusivity at the grain boundaries is lower than the calculated bulk diffusivity in a temperature range between 473 and 1473 K, although the difference between the grain boundary and bulk diffusivities decreases with increasing temperature. Compared with that of the other directions, the mean square displacement of an interstitial hydrogen atom at the Σ3 boundary is relatively small in the direction normal to the boundary, leading to two dimensional motion. Molecular statics simulations show that there is strong attraction between the hydrogen atom and these grain boundaries in V, which implies that the role of grain boundaries is to act as trap sites rather than to provide fast diffusion paths of hydrogen atoms in V.",

keywords = "computer simulation, diffusion, grain boundary, hydrogen, metals",

author = "Shim, {Jae Hyeok} and Ko, {Won Seok} and Suh, {Jin Yoo} and Lee, {Young Su} and Lee, {Byeong Joo}",

year = "2013",

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doi = "10.1007/s12540-013-6012-0",

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T1 - Atomistic simulation of hydrogen diffusion at tilt grain boundaries in vanadium

AU - Shim, Jae Hyeok

AU - Ko, Won Seok

AU - Suh, Jin Yoo

AU - Lee, Young Su

AU - Lee, Byeong Joo

PY - 2013/11

Y1 - 2013/11

N2 - Molecular dynamics simulations of hydrogen diffusion at Σ3 and Σ5 tilt grain boundaries in bcc vanadium (V) have been performed based on modified embedded-atom method interatomic potentials. The calculated diffusivity at the grain boundaries is lower than the calculated bulk diffusivity in a temperature range between 473 and 1473 K, although the difference between the grain boundary and bulk diffusivities decreases with increasing temperature. Compared with that of the other directions, the mean square displacement of an interstitial hydrogen atom at the Σ3 boundary is relatively small in the direction normal to the boundary, leading to two dimensional motion. Molecular statics simulations show that there is strong attraction between the hydrogen atom and these grain boundaries in V, which implies that the role of grain boundaries is to act as trap sites rather than to provide fast diffusion paths of hydrogen atoms in V.

AB - Molecular dynamics simulations of hydrogen diffusion at Σ3 and Σ5 tilt grain boundaries in bcc vanadium (V) have been performed based on modified embedded-atom method interatomic potentials. The calculated diffusivity at the grain boundaries is lower than the calculated bulk diffusivity in a temperature range between 473 and 1473 K, although the difference between the grain boundary and bulk diffusivities decreases with increasing temperature. Compared with that of the other directions, the mean square displacement of an interstitial hydrogen atom at the Σ3 boundary is relatively small in the direction normal to the boundary, leading to two dimensional motion. Molecular statics simulations show that there is strong attraction between the hydrogen atom and these grain boundaries in V, which implies that the role of grain boundaries is to act as trap sites rather than to provide fast diffusion paths of hydrogen atoms in V.

KW - computer simulation

KW - diffusion

KW - grain boundary

KW - hydrogen

KW - metals

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Atomistic simulation of hydrogen diffusion at tilt grain boundaries in vanadium

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