Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
Ralph, Brian
1992.
The characterization of grain boundaries.
Scripta Metallurgica et Materialia,
Vol. 27,
Issue. 11,
p.
1509.
Bulatov, V.
Nastar, M.
Justo, J.
and
Yip, S.
1997.
Atomistic modeling of crystal-defect mobility and interactions.
Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms,
Vol. 121,
Issue. 1-4,
p.
251.
Szpunar, Barbara
Lewis, Laurent J.
Swainson, Ian
and
Erb, Uwe
1999.
Thermal expansion and hydrogen diffusion in nanocrystalline nickel.
Physical Review B,
Vol. 60,
Issue. 14,
p.
10107.
Kurtz, R. J.
Hoagland, R. G.
and
Hirth, J. P.
1999.
Effect of extrinsic grain-boundary defects on grain-boundary sliding resistance.
Philosophical Magazine A,
Vol. 79,
Issue. 3,
p.
665.
Chang, Jinpeng
Cai, Wei
Bulatov, Vasily V
and
Yip, Sidney
2002.
Molecular dynamics simulations of motion of edge and screw dislocations in a metal.
Computational Materials Science,
Vol. 23,
Issue. 1-4,
p.
111.
Schönfelder, B.
Gottstein, G.
and
Shvindlerman, L.S.
2005.
Comparative study of grain-boundary migration and grain-boundary self-diffusion of [001] twist-grain boundaries in copper by atomistic simulations.
Acta Materialia,
Vol. 53,
Issue. 6,
p.
1597.
Zhou, L
Zhou, N
and
Song, G
2006.
Collective motion of atoms in grain boundary migration of a bcc metal.
Philosophical Magazine,
Vol. 86,
Issue. 36,
p.
5885.
Schönfelder, B.
Gottstein, G.
and
Shvindlerman, L. S.
2006.
Atomistic simulations of grain boundary migration in copper.
Metallurgical and Materials Transactions A,
Vol. 37,
Issue. 6,
p.
1757.
Yan, Xinan
and
Zhang, Hao
2010.
On the atomistic mechanisms of grain boundary migration in [001] twist boundaries: Molecular dynamics simulations.
Computational Materials Science,
Vol. 48,
Issue. 4,
p.
773.
Zhou, J.
and
Mohles, V.
2011.
Mobility Evaluation of <110> Twist Grain Boundary Motion from Molecular Dynamics Simulation.
steel research international,
Vol. 82,
Issue. 2,
p.
114.
Chiang, Tsu-Wu
Chernatynskiy, Aleksandr
Sinnott, Susan B.
and
Phillpot, Simon R.
2014.
Interaction between voids and grain boundaries in UO2 by molecular-dynamics simulation.
Journal of Nuclear Materials,
Vol. 448,
Issue. 1-3,
p.
53.
Wicaksono, A.T.
Sinclair, C.W.
and
Militzer, M.
2016.
An atomistic study of the correlation between the migration of planar and curved grain boundaries.
Computational Materials Science,
Vol. 117,
Issue. ,
p.
397.
Teus, S. M.
and
Gavriljuk, V. G.
2019.
Molecular Dynamics Study of the Hydrogen and Carbon Effect on Mobility of Grain Boundaries in $\alpha$-Iron.
METALLOFIZIKA I NOVEISHIE TEKHNOLOGII,
Vol. 41,
Issue. 9,
p.
1187.
Teus, S.M.
and
Gavriljuk, V.G.
2020.
On a correlation between hydrogen effects on atomic interactions and mobility of grain boundaries in the alpha-iron. Stage II. Mobility of grain boundaries in the H-charged α-iron.
Materials Letters,
Vol. 259,
Issue. ,
p.
126859.
Gavriljuk, V. G.
Shyvaniuk, V. M.
and
Teus, S. M.
2022.
Hydrogen in Engineering Metallic Materials.
p.
45.
Wang, Ke
Xu, Yongsheng
Zhang, Weigang
and
Xu, Jinquan
2023.
The impact of structural units on the dislocation nucleation of bi-crystal copper grain boundary.
Computational Materials Science,
Vol. 218,
Issue. ,
p.
111900.