过程(计算)
计算机科学
产量(工程)
工艺工程
催化作用
反应堆设计
参数统计
苯乙酮
化学反应器
化学反应工程
化学工程
材料科学
缩小
参数化设计
环加成
纳米技术
实验设计
流动化学
表面改性
工艺设计
化学过程
工艺优化
反应条件
参数化模型
响应面法
工程设计过程
作者
Cristopher Tinajero,Marcileia Zanatta,Julián E. Sánchez‐Velandia,Eduardo Garcı́a-Verdugo,Víctor Sans
标识
DOI:10.1038/s41467-025-64127-1
摘要
Digital technologies, including artificial intelligence and additive manufacturing, have revolutionized chemistry and chemical engineering. In reactor engineering, performance improvements have been enabled by novel geometries, yet design approaches have traditionally relied on human input. This study introduces Reac-Discovery, a digital platform that integrates catalytic reactor design, fabrication, and optimization based on periodic open-cell structures (POCs). It combines the parametric design and analysis of advanced structures from mathematic models (Reac-Gen), high-resolution 3D printing and functionalization of catalytic reactors (Reac-Fab) with an algorithm validating the printability of reactor designs and a self-driving laboratory (Reac-Eval), capable of parallel multi-reactor evaluations featuring real-time nuclear magnetic resonance (NMR) monitoring and machine learning (ML) optimization of process parameters and topological descriptors. Two multiphase catalytic reactions-the hydrogenation of acetophenone and the CO₂ cycloaddition-were selected as case studies, where Reac-Discovery achieved the highest reported space-time yield (STY) for a triphasic CO₂ cycloaddition using immobilized catalysts.
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