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Main Authors: Chen, Zherui, Zhang, Jiayu, Tian, Yuxuan, Liu, Zhoulin, Dai, Sining, Li, Yanghui, Chen, Cong, Tang, Dingyuan, Deng, Yajun, Liu, Qingxia
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.05769
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author Chen, Zherui
Zhang, Jiayu
Tian, Yuxuan
Liu, Zhoulin
Dai, Sining
Li, Yanghui
Chen, Cong
Tang, Dingyuan
Deng, Yajun
Liu, Qingxia
author_facet Chen, Zherui
Zhang, Jiayu
Tian, Yuxuan
Liu, Zhoulin
Dai, Sining
Li, Yanghui
Chen, Cong
Tang, Dingyuan
Deng, Yajun
Liu, Qingxia
contents Empirical force fields remain the primary tool for large-scale molecular simulation, yet their limited flexibility and transferability often hinder predictive modeling in chemically complex condensed-phase systems. Here we present ORION, a universal machine-learning force field for C, H, O, N, S, and P systems developed within the Neuroevolution Potential (NEP) framework. To enhance transferability across diverse chemical environments, ORION was trained on a chemically rich dataset constructed through an integrated top-down and bottom-up strategy, enabling accurate descriptions of complex organic configurations, reactive intermediates, and weak intermolecular interactions. ORION achieves near-density-functional-theory accuracy while retaining the efficiency required for large-scale molecular dynamics simulations. On the test set, it predicts atomic forces with substantially higher accuracy than ReaxFF while running 215.5 times faster under identical hardware conditions, making simulations on the hundreds-of-nanoseconds timescale readily accessible. The model provides a balanced description of bond breaking and formation, aromatic growth, hydrogen bonding, van der Waals interactions, and π-stacking, demonstrating strong transferability across both reactive and nonreactive systems. These results establish ORION as a practical and general force field for predictive simulations in chemistry and materials science, and provide an effective route toward universal machine-learning force fields with both high accuracy and broad applicability.
format Preprint
id arxiv_https___arxiv_org_abs_2604_05769
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle ORION: Unifying Top-Down and Bottom-Up Chemical Space Sampling for a Universal Organic Force Field
Chen, Zherui
Zhang, Jiayu
Tian, Yuxuan
Liu, Zhoulin
Dai, Sining
Li, Yanghui
Chen, Cong
Tang, Dingyuan
Deng, Yajun
Liu, Qingxia
Chemical Physics
Materials Science
Empirical force fields remain the primary tool for large-scale molecular simulation, yet their limited flexibility and transferability often hinder predictive modeling in chemically complex condensed-phase systems. Here we present ORION, a universal machine-learning force field for C, H, O, N, S, and P systems developed within the Neuroevolution Potential (NEP) framework. To enhance transferability across diverse chemical environments, ORION was trained on a chemically rich dataset constructed through an integrated top-down and bottom-up strategy, enabling accurate descriptions of complex organic configurations, reactive intermediates, and weak intermolecular interactions. ORION achieves near-density-functional-theory accuracy while retaining the efficiency required for large-scale molecular dynamics simulations. On the test set, it predicts atomic forces with substantially higher accuracy than ReaxFF while running 215.5 times faster under identical hardware conditions, making simulations on the hundreds-of-nanoseconds timescale readily accessible. The model provides a balanced description of bond breaking and formation, aromatic growth, hydrogen bonding, van der Waals interactions, and π-stacking, demonstrating strong transferability across both reactive and nonreactive systems. These results establish ORION as a practical and general force field for predictive simulations in chemistry and materials science, and provide an effective route toward universal machine-learning force fields with both high accuracy and broad applicability.
title ORION: Unifying Top-Down and Bottom-Up Chemical Space Sampling for a Universal Organic Force Field
topic Chemical Physics
Materials Science
url https://arxiv.org/abs/2604.05769