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Main Authors: Ji, Kaihua, Sun, Luning, Liu, Shusen, Zhou, Fei, Heo, Tae Wook
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.03884
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author Ji, Kaihua
Sun, Luning
Liu, Shusen
Zhou, Fei
Heo, Tae Wook
author_facet Ji, Kaihua
Sun, Luning
Liu, Shusen
Zhou, Fei
Heo, Tae Wook
contents Microstructural pattern formation, such as dendrite growth, occurs widely in materials and energy systems, significantly influencing material properties and functional performance. While the phase-field method has emerged as a powerful computational tool for modeling microstructure dynamics, its high computational cost limits its integration into practical materials design workflows. Here, we introduce a machine-learning framework using autoregressive deep surrogates trained on short trajectories from quantitative phase-field simulations of alloy solidification in limited spatial domains. Once trained, these surrogates accurately predict dendritic evolution at scalable length and time scales, achieving a speed-up of more than two orders of magnitude. Demonstrations in isothermal growth and in directional solidification of a dilute Al-Cu alloy validate their ability to predict microstructure evolution. Quantitative comparisons with phase-field benchmarks further show excellent agreement in the tip-selection constant, morphological symmetry, and primary spacing evolution.
format Preprint
id arxiv_https___arxiv_org_abs_2511_03884
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Scalable Autoregressive Deep Surrogates for Dendritic Microstructure Dynamics
Ji, Kaihua
Sun, Luning
Liu, Shusen
Zhou, Fei
Heo, Tae Wook
Materials Science
Microstructural pattern formation, such as dendrite growth, occurs widely in materials and energy systems, significantly influencing material properties and functional performance. While the phase-field method has emerged as a powerful computational tool for modeling microstructure dynamics, its high computational cost limits its integration into practical materials design workflows. Here, we introduce a machine-learning framework using autoregressive deep surrogates trained on short trajectories from quantitative phase-field simulations of alloy solidification in limited spatial domains. Once trained, these surrogates accurately predict dendritic evolution at scalable length and time scales, achieving a speed-up of more than two orders of magnitude. Demonstrations in isothermal growth and in directional solidification of a dilute Al-Cu alloy validate their ability to predict microstructure evolution. Quantitative comparisons with phase-field benchmarks further show excellent agreement in the tip-selection constant, morphological symmetry, and primary spacing evolution.
title Scalable Autoregressive Deep Surrogates for Dendritic Microstructure Dynamics
topic Materials Science
url https://arxiv.org/abs/2511.03884