Accelerating phase-field simulation of coupled microstructural evolution using autoencoder-based recurrent neural networks

Aidan Gesch; Chongze Hu

doi:10.20517/jmi.2025.23

Journal of Materials Informatics ›› 2025, Vol. 5 ›› Issue (4) :42 DOI: 10.20517/jmi.2025.23

Research Article

Accelerating phase-field simulation of coupled microstructural evolution using autoencoder-based recurrent neural networks

Aidan Gesch
, Chongze Hu ^*

Author information +

History +

PDF

Abstract

Accelerated phase-field frameworks leveraging time-dependent neural networks have recently been developed to accelerate microstructure-based phase-field simulations in both temporal and spatial domains. However, most of these frameworks have been designed for phase-field problems involving a single variable field, such as spinodal decomposition. In this study, we developed an accelerated framework for predicting the microstructural evolution of Ostwald ripening, a classical phase-field problem involving multiple interdependent parameter fields. This framework integrates various components: high-throughput phase-field simulations for generating high-quality microstructure database, autoencoder-based dimensionality reduction to transform 2D microstructure images into latent representations, and long short-term memory (LSTM) networks serving as the microstructure learning engine. Our results demonstrate that autoencoder techniques can effectively reduce the large dimension of microstructure images into 16 key values, while maintaining high accuracy in reconstructing these reduced representations back to their original space. Using these latent representations, LSTM models are employed to capture the key microstructural features of Ostwald ripening and predict their evolution over future time sequences, with a speedup of approximately 3.35 × 10⁵ times compared to the high-fidelity phase-field simulations. The accelerated framework presented in this work is the first data-driven emulation specifically designed for coupled phase-field problems, and it can be easily extended to predict other evolutionary phenomena with more complex microstructural features.

Keywords

Accelerated phase-field framework / microstructural evolution / recurrent neural networks / dimensionality reduction / Ostwald ripening

Cite this article

Download citation ▾

Aidan Gesch, Chongze Hu. Accelerating phase-field simulation of coupled microstructural evolution using autoencoder-based recurrent neural networks. Journal of Materials Informatics, 2025, 5(4): 42 DOI:10.20517/jmi.2025.23

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Chen LQ.Phase-field models for microstructure evolution.Annu Rev Mater Res2002;32:113-40

[2]	Boettinger WJ,Beckermann C.Phase-field simulation of solidification.Annu Rev Mater Res2002;32:163-94

[3]	Steinbach I.Phase-field models in materials science.Modelling Simul Mater Sci Eng2009;17:073001

[4]	Moelans N,Wollants P.An introduction to phase-field modeling of microstructure evolution.Calphad2008;32:268-94

[5]	Cahn JW.On spinodal decomposition.Acta Metall1961;9:795-801

[6]	Su Y,Wang D.Composition- and temperature-dependence of β to ω phase transformation in Ti-Nb alloys.J Mater Inf2023;3:14

[7]	Voorhees PW.The theory of Ostwald ripening.J Stat Phys1985;38:231-52

[8]	Krill III, C. E.; Chen, L. Q. Computer simulation of 3-D grain growth using a phase-field model.Acta Mater2002;50:3059-75

[9]	Moelans N,Nestler B.Comparative study of two phase-field models for grain growth.Comput Mater Sci2009;46:479-90

[10]	Moelans N,Wollants P.Quantitative analysis of grain boundary properties in a generalized phase field model for grain growth in anisotropic systems.Phys Rev B2008;78:024113

[11]	Karma A.Quantitative phase-field modeling of dendritic growth in two and three dimensions.Phys Rev E1998;57:4323-49

[12]	Warren J.Prediction of dendritic growth and microsegregation patterns in a binary alloy using the phase-field method.Acta Metall Mater1995;43:689-703

[13]	Takaki T.Phase-field modeling and simulations of dendrite growth.ISIJ Int2014;54:437-44

[14]	Stefanovic P,Provatas N.Phase-field crystals with elastic interactions.Phys Rev Lett2006;96:225504

[15]	Boussinot G,Finel A.Phase-field simulations with inhomogeneous elasticity: comparison with an atomic-scale method and application to superalloys.Acta Mater2010;58:4170-81

[16]	Shchyglo O,Salama H.Efficient finite strain elasticity solver for phase-field simulations.npj Comput Mater2024;10:1235

[17]	Kim J.Phase field computations for ternary fluid flows.Comput Methods Appl Mech Eng2007;196:4779-88

[18]	Jeong JH,Dantzig JA.Phase field model for three-dimensional dendritic growth with fluid flow.Phys Rev E2001;64:041602

[19]	Celani A,Muratore-Ginanneschi P.Phase-field model for the Rayleigh–Taylor instability of immiscible fluids.J Fluid Mech2009;622:115-34

[20]	Wu JY,Nguyen CT,Sinaie S.Chapter One - Phase-field modeling of fracture.Adv Appl Mech2020;53:1-183

[21]	Miehe C,Ulmer H.Phase field modeling of fracture in multi-physics problems. Part I. Balance of crack surface and failure criteria for brittle crack propagation in thermo-elastic solids.Comput Methods Appl Mech Eng2015;294:449-85

[22]	Miehe C,Schänzel L.Phase field modeling of fracture in multi-physics problems. Part II. Coupled brittle-to-ductile failure criteria and crack propagation in thermo-elastic–plastic solids.Comput Methods Appl Mech Eng2015;294:486-522

[23]	Dutil Y,Salah NB,Zalewski L.A review on phase-change materials: mathematical modeling and simulations.Renew Sustain Energy Rev2011;15:112-30

[24]	Bui TQ.A review of phase-field models, fundamentals and their applications to composite laminates.Eng Fract Mech2021;248:107705

[25]	Raina A.A phase-field model for fracture in biological tissues.Biomech Model Mechanobiol2016;15:479-96

[26]	Tonks MR,Millett PC,Talbot P.An object-oriented finite element framework for multiphysics phase field simulations.Comput Mater Sci2012;51:20-9

[27]	Gültekin O,Holzapfel GA.A phase-field approach to model fracture of arterial walls: theory and finite element analysis.Comput Methods Appl Mech Eng2016;312:542-66 PMCID:PMC6812523

[28]	Yue P,Feng JJ,Hu HH.Phase-field simulations of interfacial dynamics in viscoelastic fluids using finite elements with adaptive meshing.J Comput Phys2006;219:47-67

[29]	Wang C.An energy-stable and convergent finite-difference scheme for the modified phase field crystal equation.SIAM J Numer Anal2011;49:945-69

[30]	Hu Z,Wang C.Stable and efficient finite-difference nonlinear-multigrid schemes for the phase field crystal equation.J Comput Phys2009;228:5323-39

[31]	Liu H,Zhang Y.Phase-field-based lattice Boltzmann finite-difference model for simulating thermocapillary flows.Phys Rev E2013;87:013010

[32]	Gain AL.Phase-field based topology optimization with polygonal elements: a finite volume approach for the evolution equation.Struct Multidisc Optim2012;46:327-42

[33]	Chen LQ.Applications of semi-implicit Fourier-spectral method to phase field equations.Comput Phys Commun1998;108:147-58

[34]	Liu C.A phase field model for the mixture of two incompressible fluids and its approximation by a Fourier-spectral method.Physica D2003;179:211-28

[35]	Feng WM,Hu SY,Du Q.Spectral implementation of an adaptive moving mesh method for phase-field equations.J Comput Phys2006;220:498-510

[36]	Shen J.An efficient moving mesh spectral method for the phase-field model of two-phase flows.J Computat Phys2009;228:2978-92

[37]	Muranushi T.Paraiso: an automated tuning framework for explicit solvers of partial differential equations.Comput Sci Disc2012;5:015003

[38]	Yamanaka A,Ogawa S.GPU-accelerated phase-field simulation of dendritic solidification in a binary alloy.J Cryst Growth2011;318:40-5

[39]	Dingreville R,Attari V.Benchmarking machine learning strategies for phase-field problems.Modelling Simul Mater Sci Eng2024;32:065019

[40]	Teichert GH.Machine learning materials physics: surrogate optimization and multi-fidelity algorithms predict precipitate morphology in an alternative to phase field dynamics.Comput Methods Appl Mech Eng2019;344:666-93

[41]	Teichert G,Van der Ven A.Machine learning materials physics: integrable deep neural networks enable scale bridging by learning free energy functions.Comput Methods Appl Mech Eng2019;353:201-16

[42]	Wang Z,Garikipati K.Variational system identification of the partial differential equations governing the physics of pattern-formation: inference under varying fidelity and noise.Comput Methods Appl Mech Eng2019;356:44-74

[43]	Yabansu YC,Hötzer J,Nestler B.Extraction of reduced-order process-structure linkages from phase-field simulations.Acta Mater2017;124:182-94

[44]	Herman E,Dingreville R.A data-driven surrogate model to rapidly predict microstructure morphology during physical vapor deposition.Appl Math Model2020;88:589-603

[45]	Montes de Oca Zapiain, D.; Stewart, J. A.; Dingreville, R. Accelerating phase-field-based microstructure evolution predictions via surrogate models trained by machine learning methods.npj Comput Mater2021;7:471

[46]	Hu C,Dingreville R.Accelerating phase-field predictions via recurrent neural networks learning the microstructure evolution in latent space.Comput Methods Appl Mech Eng2022;397:115128

[47]	Fetni S,Hoang TV.Capabilities of auto-encoders and principal component analysis of the reduction of microstructural images; application on the acceleration of phase-field simulations.Comput Mater Sci2023;216:111820

[48]	Wu P,Ankit K.Emulating microstructural evolution during spinodal decomposition using a tensor decomposed convolutional and recurrent neural network.Comput Mater Sci2023;224:112187

[49]	Ahmad O,Mukherjee R.Accelerating microstructure modeling via machine learning: a method combining Autoencoder and ConvLSTM.Phys Rev Mater2023;7:083802

[50]	Zhou X,Cai S.Accelerating three-dimensional phase-field simulations via deep learning approaches.J Mater Sci2024;59:15727-37

[51]	Oommen V,Desai S,Karniadakis GE.Rethinking materials simulations: blending direct numerical simulations with neural operators.npj Comput Mater2024;10:1319

[52]	Jokisaari A,Guyer J,Heinonen O.Benchmark problems for numerical implementations of phase field models.Comput Mater Sci2017;126:139-51

[53]	Balluffi RW,Carter WC.Kinetics of materials. John Wiley & Sons; 2005.

[54]	Allen SM.A microscopic theory for antiphase boundary motion and its application to antiphase domain coarsening.Acta Metall1979;27:1085-95

[55]	Stewart JA.Microstructure morphology and concentration modulation of nanocomposite thin-films during simulated physical vapor deposition.Acta Mater2020;188:181-91

[56]	Monti JM,Hattar K,Boyce BL.Stability of immiscible nanocrystalline alloys in compositional and thermal fields.Acta Mater2022;226:117620

[57]	Blaiszik B,Pruyne J,Tuecke S.The materials data facility: data services to advance materials science research.JOM2016;68:2045-52

[58]	Blaiszik B,Schwarting M.A data ecosystem to support machine learning in materials science.MRS Commun2019;9:1125-33

[59]	Gesch AH.Ostwald Ripening Dataset for “Accelerating phase-field simulation of coupled microstructural evolution using autoencoder-based recurrent neural networks”. 2025.

[60]	Cho K,Gulcehre C. Learning phrase representations using RNN encoder-decoder for statistical machine translation. arXiv 2014, arXiv:1406.1078. https://doi.org/10.48550/arXiv.1406.1078. (accessed 9 Jun 2025)

[61]	Desai S,D’elia M,Dingreville R.Trade-offs in the latent representation of microstructure evolution.Acta Mater2024;263:119514

[62]	Bank D,Giryes R.Autoencoders. In: Rokach L, Maimon O, Shmueli E, editors. Machine Learning For Data Science Handbook. Cham: Springer International Publishing; 2023. pp. 353-74.

[63]	Hu A,Chen Q.A new framework for predicting tensile stress of natural rubber based on data augmentation and molecular dynamics simulation data.J Mater Inf2024;4:11

[64]	Chowdhury A,Yener B.Image driven machine learning methods for microstructure recognition.Comput Mater Sci2016;123:176-87

[65]	Chan H,Loeffler TD,Sankaranarayanan SKRS.Machine learning enabled autonomous microstructural characterization in 3D samples.npj Comput Mater2020;6:267

[66]	Creswell A,Bharath AA. On denoising autoencoders trained to minimise binary cross-entropy. arXiv 2017, arXiv:1708.08487. https://doi.org/10.48550/arXiv.1708.08487. (accessed 9 Jun 2025)

[67]	Tealab A.Time series forecasting using artificial neural networks methodologies: a systematic review.Future Comput Informatics J2018;3:334-40

[68]	Hochreiter S.Long short-term memory.Neural Comput1997;9:1735-80

[69]	Naser MZ.Error metrics and performance fitness indicators for artificial intelligence and machine learning in engineering and sciences.Archit Struct Constr2023;3:499-517

[70]	Cortes C.Support-vector networks.Mach Learn1995;20:273-97

[71]	Zhu JZ,Ardell AJ,Liu ZK.Three-dimensional phase-field simulations of coarsening kinetics of γ′ particles in binary Ni–Al alloys.Acta Mater2004;52:2837-45