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Autori principali: Uddagiri, Murali, Antala, Pankaj, Steinbach, Ingo
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2603.06627
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author Uddagiri, Murali
Antala, Pankaj
Steinbach, Ingo
author_facet Uddagiri, Murali
Antala, Pankaj
Steinbach, Ingo
contents A mesoscopic grain-envelope model applying a phase-field front-propagation method is developed to simulate grain growth under additive manufacturing process conditions. The envelope represents the outer surface of dendritic grains through a diffuse interface. While a modified heat-conduction model that incorporates moving heat sources and latent-heat release provides the evolution of local thermal field. Envelope propagation is determined from microscopic-solvability-based kinetic law. The model is validated through two- and three-dimensional simulations and subsequently applied to examine the influence of material and process parameters on microstructure evolution. The results demonstrate that the proposed mesoscopic model offers an efficient and predictive approach for modeling grain growth during multi-pass and multi-layer build-up in additive manufacturing.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06627
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Phase field as a front propagation method for modeling grain growth in additive manufacturing
Uddagiri, Murali
Antala, Pankaj
Steinbach, Ingo
Materials Science
A mesoscopic grain-envelope model applying a phase-field front-propagation method is developed to simulate grain growth under additive manufacturing process conditions. The envelope represents the outer surface of dendritic grains through a diffuse interface. While a modified heat-conduction model that incorporates moving heat sources and latent-heat release provides the evolution of local thermal field. Envelope propagation is determined from microscopic-solvability-based kinetic law. The model is validated through two- and three-dimensional simulations and subsequently applied to examine the influence of material and process parameters on microstructure evolution. The results demonstrate that the proposed mesoscopic model offers an efficient and predictive approach for modeling grain growth during multi-pass and multi-layer build-up in additive manufacturing.
title Phase field as a front propagation method for modeling grain growth in additive manufacturing
topic Materials Science
url https://arxiv.org/abs/2603.06627