转化式学习
人工智能
深度学习
计算机科学
系统工程
纳米技术
机器人学
生成语法
化学空间
钥匙(锁)
数据科学
图形
数据集成
数据驱动
机器人
机器学习
人工智能应用
人工神经网络
班级(哲学)
大数据
数据共享
财产(哲学)
作者
Yuhang Song,Jiakai Li,Dongzhi Chi,Zhengtao Xu,Jie Liu,Mingxi Chen,Ziyu Wang
摘要
Metal-organic frameworks (MOFs) are a versatile class of porous materials with unprecedented structural tunability, surface area, and application potential in areas such as gas storage, carbon capture, and biomedicine. However, their immense chemical design space poses significant challenges for conventional discovery and optimization methods. Recent advances in artificial intelligence (AI) and machine learning (ML) have introduced transformative capabilities to this field, enabling accurate property prediction, automated structure generation, and synthesis planning at scale. This review provides a comprehensive overview of AI-driven strategies for accelerating MOF research. It discusses key databases, deep learning architectures, generative models, and hybrid AI-simulation frameworks that have reshaped the design and screening of high-performance MOFs. Techniques such as graph neural networks and AL have enabled breakthroughs in structure-property prediction, while integration with robotics is advancing autonomous laboratories. Despite these advancements, challenges remain in data quality, model interpretability, and experimental validation. Future directions include physics-informed ML models, standardized data protocols, and deeper integration of AI with chemical robotics. By highlighting both opportunities and current limitations, this review aims to provide a roadmap for the next generation of AI-accelerated MOF innovation.
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