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

**Authors:** Daniel N. Blaschke, Emil Mottola, and Dean L. Preston

arXiv: 1907.00101 · 2020-03-04

## TL;DR

This paper derives analytic expressions for the velocity-dependent phonon wind drag on dislocations in isotropic crystals approaching the sound speed, highlighting the role of additional elastic constants and comparing with experimental data.

## Contribution

It introduces new elastic constants involving asymmetric strains and provides velocity-dependent drag coefficients up to near sound speed in the Debye approximation.

## Key findings

- Drag coefficient for screw dislocations remains finite as velocity approaches sound speed.
- Drag coefficient for edge dislocations diverges near the transverse sound speed.
- Results agree with some experimental data and suggest further validation methods.

## Abstract

The anharmonic interaction and scattering of phonons by a moving dislocation, the photon wind, imparts a drag force $v B(v, T, \rho)$ 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 $v \rightarrow c_t$, 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.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1907.00101/full.md

## References

64 references — full list in the complete paper: https://tomesphere.com/paper/1907.00101/full.md

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Source: https://tomesphere.com/paper/1907.00101