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Hauptverfasser: Yin, Bangchen, Ouyang, Jian, Fan, Zhen, Lin, Kailai, Hu, Hanshi, Lv, Dingshun, Ren, Weiluo, Xiao, Hai, Chen, Ji, Cao, Changsu
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.25373
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author Yin, Bangchen
Ouyang, Jian
Fan, Zhen
Lin, Kailai
Hu, Hanshi
Lv, Dingshun
Ren, Weiluo
Xiao, Hai
Chen, Ji
Cao, Changsu
author_facet Yin, Bangchen
Ouyang, Jian
Fan, Zhen
Lin, Kailai
Hu, Hanshi
Lv, Dingshun
Ren, Weiluo
Xiao, Hai
Chen, Ji
Cao, Changsu
contents Local curvature of potential energy surfaces is critical for predicting certain experimental observables of molecules and materials from first principles, yet it remains far beyond reach for complex systems. In this work, we introduce a Hessian-informed Machine Learning Interatomic Potential (Hi-MLIP) that captures such curvature reliably, thereby enabling accurate analysis of associated thermodynamic and kinetic phenomena. To make Hessian supervision practically viable, we develop a highly efficient training protocol, termed Hessian INformed Training (HINT), achieving two to four orders of magnitude reduction for the requirement of expensive Hessian labels. HINT integrates critical techniques, including Hessian pre-training, configuration sampling, curriculum learning and stochastic projection Hessian loss. Enabled by HINT, Hi-MLIP significantly improves transition-state search and brings Gibbs free-energy predictions close to chemical accuracy especially in data-scarce regimes. Our framework also enables accurate treatment of strongly anharmonic hydrides, reproducing phonon renormalization and superconducting critical temperatures in close agreement with experiment while bypassing the computational bottleneck of anharmonic calculations. These results establish a practical route to enhancing curvature awareness of machine learning interatomic potentials, bridging simulation and experimental observables across a wide range of systems.
format Preprint
id arxiv_https___arxiv_org_abs_2603_25373
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Hessian-informed machine learning interatomic potential towards bridging theory and experiments
Yin, Bangchen
Ouyang, Jian
Fan, Zhen
Lin, Kailai
Hu, Hanshi
Lv, Dingshun
Ren, Weiluo
Xiao, Hai
Chen, Ji
Cao, Changsu
Machine Learning
Local curvature of potential energy surfaces is critical for predicting certain experimental observables of molecules and materials from first principles, yet it remains far beyond reach for complex systems. In this work, we introduce a Hessian-informed Machine Learning Interatomic Potential (Hi-MLIP) that captures such curvature reliably, thereby enabling accurate analysis of associated thermodynamic and kinetic phenomena. To make Hessian supervision practically viable, we develop a highly efficient training protocol, termed Hessian INformed Training (HINT), achieving two to four orders of magnitude reduction for the requirement of expensive Hessian labels. HINT integrates critical techniques, including Hessian pre-training, configuration sampling, curriculum learning and stochastic projection Hessian loss. Enabled by HINT, Hi-MLIP significantly improves transition-state search and brings Gibbs free-energy predictions close to chemical accuracy especially in data-scarce regimes. Our framework also enables accurate treatment of strongly anharmonic hydrides, reproducing phonon renormalization and superconducting critical temperatures in close agreement with experiment while bypassing the computational bottleneck of anharmonic calculations. These results establish a practical route to enhancing curvature awareness of machine learning interatomic potentials, bridging simulation and experimental observables across a wide range of systems.
title Hessian-informed machine learning interatomic potential towards bridging theory and experiments
topic Machine Learning
url https://arxiv.org/abs/2603.25373