Machine learning accelerated photodynamics simulations

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Jingbai Li, Steven A. Lopez
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引用次数: 0

Abstract

Machine learning (ML) continues to revolutionize computational chemistry for accelerating predictions and simulations by training on experimental or accurate but expensive quantum mechanical (QM) calculations. Photodynamics simulations require hundreds of trajectories coupled with multiconfigurational QM calculations of excited-state potential energies surfaces that contribute to the prohibitive computational cost at long timescales and complex organic molecules. ML accelerates photodynamics simulations by combining nonadiabatic photodynamics simulations with an ML model trained with high-fidelity QM calculations of energies, forces, and non-adiabatic couplings. This approach has provided time-dependent molecular structural information for understanding photochemical reaction mechanisms of organic reactions in vacuum and complex environments (i.e., explicit solvation). This review focuses on the fundamentals of QM calculations and ML techniques. We, then, discuss the strategies to balance adequate training data and the computational cost of generating these training data. Finally, we demonstrate the power of applying these ML-photodynamics simulations to understand the origin of reactivities and selectivities of organic photochemical reactions, such as cis–trans isomerization, [2 + 2]-cycloaddition, 4π-electrostatic ring-closing, and hydrogen roaming mechanism.
机器学习(ML)继续革新计算化学,通过训练实验或精确但昂贵的量子力学(QM)计算来加速预测和模拟。光动力学模拟需要数百个轨迹以及激发态势能表面的多构型量子力学计算,这在长时间尺度和复杂有机分子中造成了令人望而却步的计算成本。ML通过将非绝热光动力学模拟与经过高保真QM能量、力和非绝热耦合计算训练的ML模型相结合来加速光动力学模拟。该方法为理解真空和复杂环境(即显式溶剂化)下有机反应的光化学反应机制提供了随时间变化的分子结构信息。这篇综述的重点是QM计算和ML技术的基础。然后,我们讨论了平衡足够的训练数据和生成这些训练数据的计算成本的策略。最后,我们展示了应用这些ml光动力学模拟来理解有机光化学反应的反应性和选择性的来源,如顺-反异构化、[2 + 2]-环加成、4π-静电合环和氢漫游机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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