Evaluation of Nanoscale Deformation Fields from Phase Field Crystal Simulations

Håkan Hallberg; Kevin Blixt

doi:10.3390/met12101630

Evaluation of Nanoscale Deformation Fields from Phase Field Crystal Simulations

Research output: Contribution to journal › Article › peer-review

Abstract

Different methods for evaluation of displacement and strain fields based on phase field crystal (PFC) simulations are shown. Methods originally devised for molecular dynamics (MD) simulations or analysis of high-resolution microscopy images are adapted to a PFC setting, providing access to displacement and strain fields for systems of discrete atoms, such as in MD, as well as to continuous deformation fields. The latter being achieved by geometrical phase analysis. As part of the study, the application of prescribed non-affine deformations in a 3D structural PFC (XPFC) setting is demonstrated as well as an efficient numerical scheme for evaluation of PFC phase diagrams, such as, for example, those required to stabilize solid/liquid coexistence. The present study provides an expanded toolbox for using PFC simulations as a versatile numerical method in the analysis of material behavior at the atomic scale.

Original language	English
Article number	1630
Journal	Metals
Volume	12
Issue number	10
DOIs	https://doi.org/10.3390/met12101630
Publication status	Published - 2022 Sept 28

Subject classification (UKÄ)

Applied Mechanics
Metallurgy and Metallic Materials
Atom and Molecular Physics and Optics

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3390/met12101630Licence: CC BY

Phase Field Crystal Modeling of Microstructure Mechanics
Hallberg, H. (Supervisor) & Blixt, K. (Research student)
Swedish Research Council
2020/11/02 → 2025/12/31
Project: Research

Cite this

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title = "Evaluation of Nanoscale Deformation Fields from Phase Field Crystal Simulations",

abstract = "Different methods for evaluation of displacement and strain fields based on phase field crystal (PFC) simulations are shown. Methods originally devised for molecular dynamics (MD) simulations or analysis of high-resolution microscopy images are adapted to a PFC setting, providing access to displacement and strain fields for systems of discrete atoms, such as in MD, as well as to continuous deformation fields. The latter being achieved by geometrical phase analysis. As part of the study, the application of prescribed non-affine deformations in a 3D structural PFC (XPFC) setting is demonstrated as well as an efficient numerical scheme for evaluation of PFC phase diagrams, such as, for example, those required to stabilize solid/liquid coexistence. The present study provides an expanded toolbox for using PFC simulations as a versatile numerical method in the analysis of material behavior at the atomic scale.",

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AU - Hallberg, Håkan

AU - Blixt, Kevin

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N2 - Different methods for evaluation of displacement and strain fields based on phase field crystal (PFC) simulations are shown. Methods originally devised for molecular dynamics (MD) simulations or analysis of high-resolution microscopy images are adapted to a PFC setting, providing access to displacement and strain fields for systems of discrete atoms, such as in MD, as well as to continuous deformation fields. The latter being achieved by geometrical phase analysis. As part of the study, the application of prescribed non-affine deformations in a 3D structural PFC (XPFC) setting is demonstrated as well as an efficient numerical scheme for evaluation of PFC phase diagrams, such as, for example, those required to stabilize solid/liquid coexistence. The present study provides an expanded toolbox for using PFC simulations as a versatile numerical method in the analysis of material behavior at the atomic scale.

AB - Different methods for evaluation of displacement and strain fields based on phase field crystal (PFC) simulations are shown. Methods originally devised for molecular dynamics (MD) simulations or analysis of high-resolution microscopy images are adapted to a PFC setting, providing access to displacement and strain fields for systems of discrete atoms, such as in MD, as well as to continuous deformation fields. The latter being achieved by geometrical phase analysis. As part of the study, the application of prescribed non-affine deformations in a 3D structural PFC (XPFC) setting is demonstrated as well as an efficient numerical scheme for evaluation of PFC phase diagrams, such as, for example, those required to stabilize solid/liquid coexistence. The present study provides an expanded toolbox for using PFC simulations as a versatile numerical method in the analysis of material behavior at the atomic scale.

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M3 - Article

SN - 2075-4701

VL - 12

JO - Metals

JF - Metals

IS - 10

M1 - 1630

ER -

Evaluation of Nanoscale Deformation Fields from Phase Field Crystal Simulations

Abstract

Subject classification (UKÄ)

UN SDGs

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Phase Field Crystal Modeling of Microstructure Mechanics

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