过电位
材料科学
贝叶斯优化
催化作用
异质结
纳米技术
电化学
化学工程
吸附
贝叶斯概率
贝叶斯推理
制氢
计算机科学
合理设计
拉曼光谱
氢
工作(物理)
生化工程
工艺工程
作者
Namuersaihan Namuersaihan,Zhiqiang Zhao,Oliver J. Conquest,Ying Shu,Haoyue Sun,Chunjing Su,Qi Cheng,Aloysius Soon,Catherine Stampfl,Jun Huang
标识
DOI:10.1002/adfm.202528363
摘要
ABSTRACT The hydrogen evolution reaction (HER) in alkaline media is a promising strategy for sustainable hydrogen production, but the exploration of efficient and durable HER electrocatalysts is often hindered by the empirical and time‐consuming nature of traditional synthesis. Herein, a machine learning (ML)–driven strategy combining Bayesian optimization is introduced to achieve the rational design of Ni 3 S 4 /Ni 3 Mo heterostructures for alkaline HER. By coupling predictive modeling with experimental feedback, this approach efficiently navigated a complex synthesis space and identified conditions yielding a structurally and electronically optimized catalyst. The optimized Ni 3 S 4 /Ni 3 Mo exhibits a vibrant morphological evolution—from compact buds to blooming petal‐like structures—enabling enriched active sites and accelerated mass transport. Guided by Bayesian optimization, the optimized Ni 3 S 4 /Ni 3 Mo achieves a 10.5‐fold enhancement in C dl and delivers an exceptionally low overpotential of 18.2 mV at 100 mA cm −2 , outperforming most reported transition‐metal catalysts and even surpassing commercial Pt/C. Mechanistic insights from in situ Raman and DFT reveal that interfacial charge redistribution between Ni 3 S 4 and Ni 3 Mo optimizes H* adsorption (Δ G H* ≈ 0.04 eV) and significantly reduces the water‐dissociation barrier (0.08 eV), thereby accelerating reaction kinetics. This work demonstrates how the ML‐guided optimization can synergistically couple morphology control, interfacial engineering with electronic tuning, offering a generalizable framework for intelligent catalyst discovery and mechanistic understanding in electrochemical energy conversion.
科研通智能强力驱动
Strongly Powered by AbleSci AI