Adaptive mesh computation of polycrystalline pattern formation using a renormalization-group reduction of the phase-field crystal model

Athreya, Badrinarayan P.; Goldenfeld, Nigel; Dantzig, Jonathan A.; Greenwood, Michael; Provatas, Nikolas

doi:10.1103/physreve.76.056706

Cited by 78 publications

(104 citation statements)

References 51 publications

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“…Existing modeling methods typically operate either exclusively on atomic scales or on meso-and macroscopic scales. Phase-field crystal models on the other hand provide a framework that combines atomic length scales and mesoscopic/diffusive time scales [1][2][3] , with the potential to reach mesoscopic lengths through systematic multi-scale expansion methods [4][5][6][7][8] . The PFC approach naturally incorporates elasticity, plasticity, and effects of local crystal orientation into a relatively simple atomic-level continuum theory 1,2 .…”

Section: Introductionmentioning

confidence: 99%

Defect stability in phase-field crystal models: Stacking faults and partial dislocations

et al. 2012

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The primary factors controlling defect stability in phase-field crystal (PFC) models are examined, with illustrative examples involving several existing variations of the model. Guidelines are presented for constructing models with stable defect structures that maintain high numerical efficiency. The general framework combines both long-range elastic fields and basic features of atomic-level core structures, with defect dynamics operable over diffusive time scales. Fundamental elements of the resulting defect physics are characterized for the case of fcc crystals. Stacking faults and split Shockley partial dislocations are stabilized for the first time within the PFC formalism, and various properties of associated defect structures are characterized. These include the dissociation width of perfect edge and screw dislocations, the effect of applied stresses on dissociation, Peierls strains for glide, and dynamic contraction of gliding pairs of partials. Our results in general are shown to compare favorably with continuum elastic theories and experimental findings.

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Section: Introductionmentioning

confidence: 99%

Defect stability in phase-field crystal models: Stacking faults and partial dislocations

et al. 2012

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“…The combination of the two can describe dislocations and grain boundaries, since the phase can be discontinuous when the magnitude goes to zero. This approach allows for larger length and time scales, and as shown by Athreya et al [27] can be numerically implemented using efficient multigrid methods. It is also very useful for studies in which the crystal orientation is almost the same everywhere (except near dislocations) as in the case of heteroepitaxial systems [28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Phase-field-crystal models and mechanical equilibrium

et al. 2014

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Phase-field-crystal (PFC) models constitute a field theoretical approach to solidification, melting, and related phenomena at atomic length and diffusive time scales. One of the advantages of these models is that they naturally contain elastic excitations associated with strain in crystalline bodies. However, instabilities that are diffusively driven towards equilibrium are often orders of magnitude slower than the dynamics of the elastic excitations, and are thus not included in the standard PFC model dynamics. We derive a method to isolate the time evolution of the elastic excitations from the diffusive dynamics in the PFC approach and set up a two-stage process, in which elastic excitations are equilibrated separately. This ensures mechanical equilibrium at all times. We show concrete examples demonstrating the necessity of the separation of the elastic and diffusive time scales. In the small-deformation limit this approach is shown to agree with the theory of linear elasticity.

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“…Deformations of the crystal lattice can be represented by spatial variations in the phase of the amplitude. Using this amplitude representation, Athreya et al [28] were able to apply adaptive mesh refinement to simulate grain growth on micron scales while simultaneously resolving atomic scale structures at interfaces. This remarkable achievement suggests that the development of amplitude expansions is very promising for computational materials research.…”

Section: Introductionmentioning

confidence: 99%

Amplitude expansion of the binary phase-field-crystal model

2010

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Amplitude representations of a binary phase field crystal model are developed for a two dimensional triangular lattice and three dimensional BCC and FCC crystal structures. The relationship between these amplitude equations and the standard phase field models for binary alloy solidification with elasticity are derived, providing an explicit connection between phase field crystal and phase field models. Sample simulations of solute migration at grain boundaries, eutectic solidification and quantum dot formation on nano-membranes are also presented.

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Adaptive mesh computation of polycrystalline pattern formation using a renormalization-group reduction of the phase-field crystal model

Cited by 78 publications

References 51 publications

Defect stability in phase-field crystal models: Stacking faults and partial dislocations

Defect stability in phase-field crystal models: Stacking faults and partial dislocations

Phase-field-crystal models and mechanical equilibrium

Amplitude expansion of the binary phase-field-crystal model

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