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Main Authors: Hu, Bo, Liu, Siyu, Ye, Beilin, Hao, Yun, Liu, Yanhui, Lu, Yang, Li, Ju, Srolovitz, David J., Wen, Tongqi
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.16416
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author Hu, Bo
Liu, Siyu
Ye, Beilin
Hao, Yun
Liu, Yanhui
Lu, Yang
Li, Ju
Srolovitz, David J.
Wen, Tongqi
author_facet Hu, Bo
Liu, Siyu
Ye, Beilin
Hao, Yun
Liu, Yanhui
Lu, Yang
Li, Ju
Srolovitz, David J.
Wen, Tongqi
contents Discovering explicit physical laws has traditionally depended on human intuition and domain expertise. Recent advances in artificial intelligence, particularly large language models (LLMs), offer a new route to accelerate this process by automating key steps from hypothesis generation to interpretable model construction. Here we develop an LLM-based multi-agent framework for physical-law discovery that integrates literature-guided variable selection, hypothesis formulation, symbolic regression, formula derivation, and mechanistic explanation. We validate the framework on three representative materials problems: the glass-forming ability (GFA) of metallic glasses, the Vickers hardness of compounds, and the Young's modulus of multi-component alloys. Using physically and chemically meaningful descriptors as inputs, the discovered formulas achieve strong agreement with reference data, with correlation coefficients up to 0.94 (GFA), 0.86 (hardness), and 0.94 (Young's modulus), while remaining compact and interpretable. Beyond fitting, the Young's modulus formula generalizes to quaternary and quinary alloys, improving prediction accuracy by up to 78.8% relative to the classical rule of mixtures. By integrating cross-disciplinary knowledge, reflection mechanisms, and expert-like reasoning ability into symbolic regression, our AI-centric framework offers a robust and extensible platform for automated physical laws discovery, demonstrating that AI can increasingly serve as an essential role in modern scientific research by thinking and acting like field experts.
format Preprint
id arxiv_https___arxiv_org_abs_2411_16416
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Multi-agent Framework for Physical Laws Discovery
Hu, Bo
Liu, Siyu
Ye, Beilin
Hao, Yun
Liu, Yanhui
Lu, Yang
Li, Ju
Srolovitz, David J.
Wen, Tongqi
Materials Science
Computational Physics
Discovering explicit physical laws has traditionally depended on human intuition and domain expertise. Recent advances in artificial intelligence, particularly large language models (LLMs), offer a new route to accelerate this process by automating key steps from hypothesis generation to interpretable model construction. Here we develop an LLM-based multi-agent framework for physical-law discovery that integrates literature-guided variable selection, hypothesis formulation, symbolic regression, formula derivation, and mechanistic explanation. We validate the framework on three representative materials problems: the glass-forming ability (GFA) of metallic glasses, the Vickers hardness of compounds, and the Young's modulus of multi-component alloys. Using physically and chemically meaningful descriptors as inputs, the discovered formulas achieve strong agreement with reference data, with correlation coefficients up to 0.94 (GFA), 0.86 (hardness), and 0.94 (Young's modulus), while remaining compact and interpretable. Beyond fitting, the Young's modulus formula generalizes to quaternary and quinary alloys, improving prediction accuracy by up to 78.8% relative to the classical rule of mixtures. By integrating cross-disciplinary knowledge, reflection mechanisms, and expert-like reasoning ability into symbolic regression, our AI-centric framework offers a robust and extensible platform for automated physical laws discovery, demonstrating that AI can increasingly serve as an essential role in modern scientific research by thinking and acting like field experts.
title A Multi-agent Framework for Physical Laws Discovery
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2411.16416