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Atomistic simulations of dislocation mobility in Al, Ni and Al/Mg alloys

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arxiv cond-mat/0412324 v1 pith:JPXZ7SLP submitted 2004-12-13 cond-mat.mtrl-sci

Atomistic simulations of dislocation mobility in Al, Ni and Al/Mg alloys

classification cond-mat.mtrl-sci
keywords velocitydislocationvelocitiesappliedpurestressdislocationsedge
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Dislocation velocities and mobilities are studied by Molecular Dynamics simulations for edge and screw dislocations in pure aluminum and nickel, and edge dislocations in Al-2.5%Mg and Al-5.0%Mg random substitutional alloys using EAM potentials. In the pure materials, the velocities of all dislocations are close to linear with the ratio of (applied stress)/(temperature) at low velocities, consistent with phonon drag models and quantitative agreement with experiment is obtained for the mobility in Al. At higher velocities, different behavior is observed. The edge dislocation velocity remains dependent solely on (applied stress)/(temperature) up to approximately 1.0 MPa/K, and approaches a plateau velocity that is lower than the smallest "forbidden" speed predicted by continuum models. In contrast, above a velocity around half of the smallest continuum wave speed, the screw dislocation damping has a contribution dependent solely on stress with a functional form close to that predicted by a radiation damping model of Eshelby. At the highest applied stresses, there are several regimes of nearly constant (transonic or supersonic) velocity separated by velocity gaps in the vicinity of forbidden velocities; various modes of dislocation disintegration and destabilization were also encountered in this regime. In the alloy systems, there is a temperature- and concentration-dependent pinning regime where the velocity drops sharply below the pure metal velocity. Above the pinning regime but at moderate stresses, the velocity is again linear in (applied stress)/(temperature) but with a lower mobility than in the pure metal.

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Cited by 2 Pith papers

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    Derives a computationally efficient method for limiting velocities of edge dislocations with reflection symmetry in anisotropic crystals where prior approaches were slow.

  2. Computationally efficient method for determining limiting velocities of edge dislocations in anisotropic crystals

    cond-mat.mtrl-sci 2026-06 unverdicted novelty 5.0

    A new analytic reduction computes limiting velocities of reflection-symmetric edge dislocations two orders of magnitude faster than prior methods, including when c'16 or c'26 are nonzero.