Coupling continuum dislocation transport with crystal plasticity for application to shock loading conditions

Luscher, Darby J.; Mayeur, Jason R.; Mourad, Hashem M.; Hunter, Abigail; Kenamond, Mark A.

doi:10.1016/j.ijplas.2015.07.007

Cited by 75 publications

(49 citation statements)

References 78 publications

(75 reference statements)

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“…Hence, many dislocation based material strength models require the dislocation drag coefficient B as one of their input parameters (typically determining the dislocation glide time between obstacles), see e.g. [1][2][3][4][5][6][7]. B is usually assumed to be a constant (or a constant over a simple "relativistic" factor) as a fist order approximation.…”

Section: Introductionmentioning

confidence: 99%

Velocity dependent dislocation drag from phonon wind and crystal geometry

Blaschke

2019

Journal of Physics and Chemistry of Solids

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The mobility of dislocations is an important factor in understanding material strength. Dislocations experience a drag due to their interaction with the crystal structure, the dominating contribution at high stress and temperature being the scattering off phonons due to phonon wind. Yet, the velocity dependence of this effect has eluded a good theoretical understanding. In a previous paper, dislocation drag from phonon wind as a function of velocity was computed from first principles in the isotropic limit, in part for simplicity, but also arguing that macroscopically, a polycrystalline metal looks isotropic. However, since the single crystal grains are typically a few microns up to a millimeter in size, dislocations travel in single crystals and cross boundaries, but never actually see an isotropic material. In this work we therefore highlight the effect of crystal anisotropy on dislocation drag by accounting for the crystal and slip plane geometries. In particular, we keep the phonon spectrum isotropic for simplicity, but dislocations are modeled according to the crystal symmetry (bcc, fcc, hcp, etc.). We then compare to the earlier purely isotropic results, as well as to experimental data and MD simulations where they are available.

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Section: Introductionmentioning

confidence: 99%

Velocity dependent dislocation drag from phonon wind and crystal geometry

Blaschke

2019

Journal of Physics and Chemistry of Solids

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“…We note that drag is initially dominated by thermal effects at very low dislocation velocities, and that phonon wind becomes important only at velocities of the order of 1% transverse sound speed and higher.2 Many authors estimate the velocity dependence of the drag coefficient by means of "relativistic" factors ∝ 1/(1 − v 2 /c 2 ) m with different exponents m and a limiting (sound) speed c based on purely empirical arguments which lack a first-principles theoretical framework, see[3][4][5][6][7] and references therein.…”

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confidence: 99%

Dislocation drag from phonon wind in an isotropic crystal at large velocities

Blaschke

Mottola

Preston

2019

Philosophical Magazine

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The anharmonic interaction and scattering of phonons by a moving dislocation, the photon wind, imparts a drag force v B (v, T, ρ) on the dislocation. In early studies the drag coefficient B was computed and experimentally determined only for dislocation velocities v much less than transverse sound speed, c T . In this paper we derive analytic expressions for the velocity dependence of B up to c T in terms of the third-order continuum elastic constants of an isotropic crystal, in the continuum Debye approximation, valid for dislocation velocities approaching the sound speed. In so doing we point out that the most general form of the third order elastic potential for such a crystal and the dislocation-phonon interaction requires two additional elastic constants involving asymmetric local rotational strains, which have been neglected previously. We compute the velocity dependence of the transverse phonon wind contribution to B in the range 1%-90% c T for Al, Cu, Fe, and Nb in the isotropic Debye approximation. The drag coefficient for transverse phonons scattering from screw dislocations is finite as v → c T , whereas B is divergent for transverse phonons scattering from edge dislocations in the same limit. This divergence indicates the breakdown of the Debye approximation and sensitivity of the drag coefficient at very high velocities to the microscopic crystalline lattice cutoff. We compare our results to experimental results wherever possible and identify ways to validate and further improve the theory of dislocation drag at high velocities with realistic phonon dispersion relations, inclusion of lattice cutoff effects, MD simulation data, and more accurate experimental measurements. arXiv:1907.00101v2 [cond-mat.mtrl-sci] 1 Oct 2019

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“…Such investigation represents a bottom-up nanoscale understanding of the dislocation-GB interactions, which can then be captured more accurately by the modelling efforts at micro-and meso-scales. Examples of such efforts include the molecular dynamics level [19,33,35,60], Discrete Dislocation Dynamics approach [82][83][84][85], crystal plasticity framework [86][87][88] and continuum description [89][90][91] of dislocation pile-ups in such cases can be described either explicitly using discrete approaches or implicitly using continuum approaches. In the discrete approach, the treatment of interaction forces among the piled-up dislocations leads to a set of nonlinear equations for their equilibrium positions [92].…”

Section: Discussionmentioning

confidence: 99%

Interaction of run-in edge dislocations with twist grain boundaries in Al-a molecular dynamics study

Chandra

Kumar

Samal

et al. 2016

Philosophical Magazine

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Grain boundaries play an important role in outlining the mechanical properties of crystalline materials. They act as sites for absorption/nucleation of dislocations, which are the main carriers of plastic deformation. In view of this, the interactions between edge dislocations and twist grain boundaries-dislocation pileup, dislocation absorption and dislocation emission were explored by performing molecular dynamics simulations in face-centered cubic Al using embedded atom method. The <1 1 0> twist grain boundaries with various misorientation angles were selected for this purpose. It was found that the misorientation angle of boundary and stress anomalies arising from repeated dislocation absorption at the grain boundaries are the important parameters in determining the ability of the boundary to emit dislocations. Complex network of dislocations results in later stages of deformation, which may have a significant effect on the mechanical properties of the material. The peculiarities of dislocation nucleation, their emission from twist grain boundaries and the ramifications of this study towards development of higher length scale material models are discussed. ARTICLE HISTORY

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Coupling continuum dislocation transport with crystal plasticity for application to shock loading conditions

Cited by 75 publications

References 78 publications

Velocity dependent dislocation drag from phonon wind and crystal geometry

Velocity dependent dislocation drag from phonon wind and crystal geometry

Dislocation drag from phonon wind in an isotropic crystal at large velocities

Interaction of run-in edge dislocations with twist grain boundaries in Al-a molecular dynamics study

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