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1. Field dislocation mechanics and phase field crystal models

   https://doi.org/10.1103/PhysRevB.102.064109  

   Acharya, Amit; Viñals, Jorge (August 2020, Physical Review B)

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2. Elasticity versus phase field driven motion in the phase field crystal model

   https://doi.org/10.1088/1361-651X/ac860b  

   Acharya, Amit; Angheluta, Luiza; Viñals, Jorge (August 2022, Modelling and Simulation in Materials Science and Engineering)

   Abstract The inherent inconsistency in identifying the phase field in the phase field crystal theory with the material mass and, simultaneously, with material distortion is discussed. In its current implementation, elastic relaxation in the phase field crystal occurs on a diffusive time scale through a dissipative permeation mode. The very same phase field distortion that is included in solid elasticity drives diffusive motion, resulting in a non physical relaxation of the phase field crystal. We present two alternative theories to remedy this shortcoming. In the first case, it is assumed that the phase field only determines the incompatible part of the elastic distortion, and therefore one is free to specify an additional compatible distortion so as to satisfy mechanical equilibrium at all times (in the quasi static limit). A numerical solution of the new model for the case of a dislocation dipole shows that, unlike the classical phase field crystal model, it can account for the known law of relative motion of the two dislocations in the dipole. The physical origin of the compatible strain in this new theory remains to be specified. Therefore, a second theory is presented in which an explicit coupling between independent distortion and phase field accounts for the time dependence of the relaxation of fluctuations in both. Preliminary details of its implementation are also given. 

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3. Phase field approach for nanoscale interactions between crack propagation and phase transformation

   https://doi.org/10.1039/C9NR05960A  

   Jafarzadeh, Hossein; Levitas, Valery I.; Farrahi, Gholam Hossein; Javanbakht, Mahdi (November 2019, Nanoscale)

   The phase field approach (PFA) for the interaction of fracture and martensitic phase transformation (PT) is developed, which includes the change in surface energy during PT and the effect of unexplored scale parameters proportional to the ratio of the widths of the crack surface and the phase interface, both at the nanometer scale. The variation of these two parameters causes unexpected qualitative and quantitative effects: shift of PT away from the crack tip, “wetting” of the crack surface by martensite, change in the structure and geometry of the transformed region, crack trajectory, and process of interfacial damage evolution, as well as transformation toughening. The results suggest additional parameters controlling coupled fracture and PTs. 

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4. Phase field modeling and numerical algorithm for two-phase dielectric fluid flows

   https://doi.org/10.1016/j.jcp.2024.113228  

   Yang, Jielin; Christov, Ivan C; Dong, Suchuan (October 2024, Journal of Computational Physics)
5. Variational Phase Field Formulations of Polarization and Phase Transition in Ferroelectric Thin Films

   https://doi.org/10.1137/19M1291431  

   Du, Qiang; Li, Ruotai; Zhang, Lei (January 2020, SIAM Journal on Applied Mathematics)