贝叶斯优化
工作(物理)
生产(经济)
氯
工艺工程
计算机科学
催化作用
工程类
生化工程
贝叶斯概率
机器人
控制工程
机器人学
系统工程
生产成本
可持续能源
最优化问题
多目标优化
反应条件
化学
作者
Ruyu Yang,Donglai Zhou,Zijin Jia,Yulan Han,Lianyou Tang,Zifan Jiang,Xiaolin Tai,Yuhai Cai,Wenhui Zhong,Yue Lin,Hao Wang,Jixian Xu,Y Huang,Jun Jiang,Qing Zhu
摘要
ABSTRACT The electrocatalytic chlorine evolution reaction (CER) is essential to modern chlor‐alkali industry, yet conventional RuO 2 catalysts suffer from parasitic oxygen evolution. High‐entropy ruthenium oxides (Ru‐HEO) are promising alternatives, but their practical design is hindered by complex composition‐structure‐performance relationship. Herein, we construct a Pareto‐guided multi‐objective Bayesian optimization framework to enable autonomous high‐throughput exploration of quinary Ru‐HEO system. Through this trade‐off strategy, we identify compositions that efficiently balance mass activity, Cl 2 selectivity and material cost. The leading Ru‐HEO catalyst with only 8.4 at% Ru achieves a remarkable activity of 5083 A g −1 Ru at 1.50 V versus RHE and maintains excellent 100‐h stability, outperforming commercial RuO 2 and the state‐of‐the‐art catalysts reported. Integrated into a photovoltaic‐electrochemical (PV‐EC) prototype device and tested under simulated diurnal illumination, it sustains >95% selectivity, a maximum solar‐to‐chemical (STC) efficiency of 14.6% and projected Cl 2 production costs as low as $0.177 per kg. Our work establishes a closed‐loop, AI‐accelerated research paradigm that integrates multi‐objective optimization with robotic experimentation, offering a generalizable and expedited pathway toward high‐performance electrocatalysts for sustainable chemicals manufacturing.
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