Numerical Benchmark of Phase-Field Simulations with Elastic Strains: Precipitation in the Presence of Chemo-Mechanical Coupling

Kamachali, Reza Darvishi; Schwarze, Christian; Lin, Mingxuan; Diehl, Martin; Shanthraj, Pratheek; Prahl, Ulrich; Steinbach, Ingo; Raabe, Dierk

doi:10.1016/j.commatsci.2018.09.011

Cited by 19 publications

(8 citation statements)

References 81 publications

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“…We have compared results from the following three numerical combinations: OpenPhase only, DAMASK only and the OpenPhase chemical solver coupled with the DAMASK mechanical solver. All numerical results agree well with each other with a mean deviation of around 5% (for the concentration field including the diffusive interface area) [97].…”

Section: Benchmarkingsupporting

confidence: 76%

Modeling Bainitic Transformations during Press Hardening

et al. 2021

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We revisit recent findings on experimental and modeling investigations of bainitic transformations under the influence of external stresses and pre-strain during the press hardening process. Experimentally, the transformation kinetics in 22MnB5 under various tensile stresses are studied both on the macroscopic and microstructural level. In the bainitic microstructure, the variant selection effect is analyzed with an optimized prior-austenite grain reconstruction technique. The resulting observations are expressed phenomenologically using a autocatalytic transformation model, which serves for further scale bridging descriptions of the underlying thermo-chemo-mechanical coupling processes during the bainitic transformation. Using analyses of orientation relationships, thermodynamically consistent and nondiagonal phase field models are developed, which are supported by ab initio generated mechanical parameters. Applications are related to the microstructure evolution on the sheaf, subunit, precipitate and grain boundary level.

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Section: Benchmarkingsupporting

confidence: 76%

Modeling Bainitic Transformations during Press Hardening

et al. 2021

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“…In this overview article published on the occasion of AEM 's 20th anniversary, we present recent application examples showing how DAMASK can be used to investigate the response of metallic microstructures to applied loads. While, due to DAMASKs origin as a crystal plasticity framework, most examples presented here deal with the materials response to mechanical loads, they also demonstrate—along with several recent publications—its capabilities as a multiphysics ICME tool. The examples presented here are mainly based on existing publications and include yield‐surface‐based forming simulations, Lankford value predictions, and the forecast of damage in multiphase steels.…”

Section: Introductionmentioning

confidence: 71%

Solving Material Mechanics and Multiphysics Problems of Metals with Complex Microstructures Using DAMASK—The Düsseldorf Advanced Material Simulation Kit

et al. 2020

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Predicting process–structure and structure–property relationships are the key tasks in materials science and engineering. Central to both research directions is the internal material structure. In the case of metallic materials for structural applications, this internal structure, the microstructure, is the collective ensemble of all equilibrium and nonequilibrium lattice imperfections. Continuum models to derive process–structure and structure–property relationships are based on two ingredients: 1) quantitative state variables that capture the essential features of the material's state and 2) kinetic equations for the state that describe its evolution under load. Successful models, that is, models that are of practical use, depend on state variables and corresponding evolution laws that are sufficiently representative for the microstructure and that are able to describe the phenomena of interest. The development of software tools capable to integrate these different aspects to get a holistic view of process–structure–property relationships requires joint efforts from specialists in different disciplines and a long‐term perspective. The Düsseldorf Advanced Material Simulation Kit (DAMASK) is such a tool. In this overview article published on the occasion of Advanced Engineering Materials' 20th anniversary, some representative application examples which demonstrate how DAMASK can be used to study metallic microstructures at different length scales are presented.

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“…A multi-phase-field (MPF) model is used through the open-source microstructure simulation package OpenPhase [ 39 , 40 ]. On a given volume Ω , a general free energy density can be split into interfacial

, chemical

and elastic

contributions [ 41 , 42 , 43 , 44 ],

where N is the local number of phases and the sum constraint

is everywhere fulfilled.…”

Section: Model Descriptionsmentioning

confidence: 99%

“…

is the diffusion potential of component i in phase α. The chemo-mechanical effects were introduced by considering a linear composition dependence of elastic constants as detailed in [ 10 , 39 ].…”

Section: Model Descriptionsmentioning

confidence: 99%

Simulation of the θ′ Precipitation Process with Interfacial Anisotropy Effects in Al-Cu Alloys

Bilal

Häusler

et al. 2021

Materials

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The effects of anisotropic interfacial properties and heterogeneous elasticity on the growth and ripening of plate-like θ’-phase (Al2Cu) in Al-1.69 at.% Cu alloy are studied. Multi-phase-field simulations are conducted and discussed in comparison with aging experiments. The precipitate/matrix interface is considered to be anisotropic in terms of its energy and mobility. We find that the additional incorporation of an anisotropic interfacial mobility in conjunction with the elastic anisotropy result in substantially larger aspect ratios of the precipitates closer to the experimental observations. The anisotropy of the interfacial energy shows comparably small effect on the precipitate’s aspect ratio but changes the interface’s shape at the rim. The effect of the chemo-mechanical coupling, i.e., the composition dependence of the elastic constants, is studied as well. We show that the inverse ripening phenomenon, recently evidenced for δ’ precipitates in Al-Li alloys (Park et al. Sci. Rep. 2019, 9, 3981), does not establish for the θ’ precipitates. This is because of the anisotropic stress fields built around the θ’ precipitates, stemming from the precipitate’s shape and the interaction among different variants of the θ’ precipitate, that disturb the chemo-mechanical effects. These results show that the chemo-mechanical effects on the precipitation ripening strongly depend on the degree of sphericity and elastic isotropy of the precipitate and matrix phases.

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Numerical Benchmark of Phase-Field Simulations with Elastic Strains: Precipitation in the Presence of Chemo-Mechanical Coupling

Cited by 19 publications

References 81 publications

Modeling Bainitic Transformations during Press Hardening

Modeling Bainitic Transformations during Press Hardening

Solving Material Mechanics and Multiphysics Problems of Metals with Complex Microstructures Using DAMASK—The Düsseldorf Advanced Material Simulation Kit

Simulation of the θ′ Precipitation Process with Interfacial Anisotropy Effects in Al-Cu Alloys

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