计算机科学
过渡状态
量子
人工智能
国家(计算机科学)
过渡态理论
机器学习
势能
能量(信号处理)
势能面
统计物理学
量子态
化学
生物系统
随机矩阵
人工神经网络
算法
能量最小化
化学动力学
动力学
过渡(遗传学)
量子机器学习
数学
数学优化
作者
Kaipai Ren,Kun Tang,Yujing Zhao,Lei Zhang,Jian Du,Qingwei Meng,Qilei Liu
标识
DOI:10.1038/s41467-026-72945-0
摘要
Understanding reaction kinetics is fundamental to organic synthesis, yet traditional quantum chemistry-based transition state searches are computationally expensive. Here we present DeePEST-OS, a reactive machine learning potential designed for rapid and accurate transition state optimization and energy barrier prediction spanning ten chemical elements. Trained on approximately 75,000 reactions generated by a low-cost data preparation strategy, this model integrates physical priors from semi-empirical quantum chemistry with equivariant message passing networks to predict potential energy surfaces nearly 10,000 times faster than quantum chemistry methods, while achieving high accuracy for transition state geometry (averaged root mean square deviation of 0.12 Å) and energy barriers (mean absolute error of 0.60 kcal/mol) on unseen reactions. DeePEST-OS enables practical applications including transition state conformer screening, barrier prediction for retrosynthesis of complex pharmaceuticals, and experimentally validated diastereoselectivity prediction in Diels-Alder reactions. Collectively, these results establish DeePEST-OS as a powerful tool for accelerating reaction kinetics studies in multi-element organic synthesis.
科研通智能强力驱动
Strongly Powered by AbleSci AI