Recent Advances in Electrochemical Water Splitting Electrocatalysts: Categorization by Parameters and Catalyst Types

分类 电化学 分解水 催化作用 材料科学 纳米技术 化学工程 计算机科学 化学 工程类 人工智能 电极 物理化学 光催化 有机化学
作者
P. Silambarasan,Indira Pokhrel,U.S. Khan Muhammad,Xiaodong Shao,Yeonsu Han,Min-Seo Kim,Hyoyoung Lee
出处
期刊:ACS materials letters [American Chemical Society]
卷期号:6 (8): 3625-3666 被引量:59
标识
DOI:10.1021/acsmaterialslett.4c00587
摘要

Hydrogen energy, heralded as a novel, clean, and highly efficient energy source, stands at the forefront of initiatives aimed at decarbonizing and fostering a sustainable carbon-neutral economy. Recent strides in hydrogen production through water splitting have marked significant progress, leveraging its inherent benefits, such as zero carbon emissions, safety, and exceptional product purity. Despite these advancements, challenges persist in surmounting the substantial energy barrier and water-splitting costs. Many efficient electrocatalysts have been innovatively designed and reported to address these hurdles. However, the translation of these advances into industrial-scale applications faces multifaceted obstacles. Urgent demands for high-performance electrocatalysts meeting industrial standards underscore the imperative for a deeper comprehension of water-splitting systems. This review delves into the latest developments in water electrolysis, synthesizing experimental findings and promising strategies with different electrochemical parameters along with high entropy metals, doping engineering, interface construction, and defect engineering. Despite considerable strides in creating efficient water-splitting electrocatalysts and numerous recent investigations, numerous challenges persist, impeding the widespread industrial implementation of electrolytic water splitting. By providing a comprehensive overview, this review aims to furnish a knowledge-driven framework in fundamental science while fostering inspiration for technical engineering endeavors to craft efficient electrocatalysts tailored for water splitting.
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