范围(计算机科学)
生化工程
生物分子
计算机科学
化学
简单(哲学)
纳米技术
数据科学
自然发生
计算模型
人工生命
自然(考古学)
量子化学
管理科学
化学反应
化学演化
自催化反应
工程类
实验数据
化学反应动力学
生命系统
进化系统
作者
Olaia Anton,Guillaume Stirnemann
标识
DOI:10.1002/syst.202500057
摘要
ABSTRACT The emergence of life from abiotic chemical systems remains a central and unresolved question in natural sciences. Understanding how simple molecules gave rise to the first biomolecules and self‐sustaining reaction networks requires integrating scarce experimental data with advanced computational methods. Machine learning (ML) is rapidly transforming research in prebiotic chemistry. In particular, ML‐based interatomic potentials enable the exploration of complex reaction mechanisms at near‐quantum accuracy and reduced computational cost. Beyond individual reactions, ML methods can also accelerate the study of chemical reaction networks by predicting transition states, reaction outcomes, and kinetic parameters. Here, we highlight recent methodological and conceptual advances, illustrating how ML complements traditional quantum chemical approaches. We further discuss emerging strategies for integrating data‐driven models with experimental and theoretical frameworks, expanding the scope and efficiency of research into the chemical origins of life.
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