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Main Authors: Song, Xinyuan, Deng, Chuang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.02372
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author Song, Xinyuan
Deng, Chuang
author_facet Song, Xinyuan
Deng, Chuang
contents Interfaces in materials are often treated as massless geometric boundaries, and many kinetic models adopt an overdamped assumption. In this Letter, we show that grain boundaries exhibit inertial behavior under high-frequency oscillatory loading and introduce a quantitative method to determine their effective mass from the phase lag between the applied force and interface velocity. The measured effective mass correlates with the mass of atoms participating in interface migration. Using this advance, we reassess prevailing theories and identify regimes where the inertial term materially affects interfacial kinetics, particularly at high frequencies relevant to thermal fluctuations. These results motivate incorporating an effective mass into kinetic descriptions, providing a clearer basis for modeling and interpreting interface migration.
format Preprint
id arxiv_https___arxiv_org_abs_2512_02372
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Effective Mass of a Migrating Interface
Song, Xinyuan
Deng, Chuang
Materials Science
Interfaces in materials are often treated as massless geometric boundaries, and many kinetic models adopt an overdamped assumption. In this Letter, we show that grain boundaries exhibit inertial behavior under high-frequency oscillatory loading and introduce a quantitative method to determine their effective mass from the phase lag between the applied force and interface velocity. The measured effective mass correlates with the mass of atoms participating in interface migration. Using this advance, we reassess prevailing theories and identify regimes where the inertial term materially affects interfacial kinetics, particularly at high frequencies relevant to thermal fluctuations. These results motivate incorporating an effective mass into kinetic descriptions, providing a clearer basis for modeling and interpreting interface migration.
title Effective Mass of a Migrating Interface
topic Materials Science
url https://arxiv.org/abs/2512.02372