Abstract
We introduce a dislocation density tensor and derive its kinematic evolution law from a phase field description of crystal deformations in three dimensions. The phase field crystal (PFC) model is used to define the lattice distortion, including topological singularities, and the associated configurational stresses. We derive an exact expression for the velocity of dislocation line determined by the phase field evolution, and show that dislocation motion in the PFC is driven by a Peach–Koehler force. As is well known from earlier PFC model studies, the configurational stress is not divergence free for a general field configuration. Therefore, we also present a method (PFCMEq) to constrain the diffusive dynamics to mechanical equilibrium by adding an independent and integrable distortion so that the total resulting stress is divergence free. In the PFCMEq model, the far-field stress agrees very well with the predictions from continuum elasticity, while the near-field stress around the dislocation core is regularized by the smooth nature of the phase-field. We apply this framework to study the rate of shrinkage of an dislocation loop seeded in its glide plane.
Original language | English (US) |
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Article number | 104932 |
Journal | Journal of the Mechanics and Physics of Solids |
Volume | 166 |
DOIs | |
State | Published - Sep 2022 |
Externally published | Yes |
Bibliographical note
Funding Information:V.S. and L.A. acknowledge support from the Research Council of Norway through the Center of Excellence funding scheme, Project No. 262644 (PoreLab). M.S. acknowledges support from the Emmy Noether Programme of the German Research Foundation (DFG) under Grant No. SA4032/2-1 . The research of J.V. is supported by the National Science Foundation, USA , contract No. DMR-1838977 .
Publisher Copyright:
© 2022 The Author(s)
Keywords
- Atomistic models
- Computational methods
- Crystal plasticity
- Dislocation dynamics
- Phase-field crystal modeling
- Structure of solids and liquids