Single-atom catalysts supported on atomically thin materials for water splitting

材料科学 Atom(片上系统) 催化作用 分解水 纳米技术 化学物理 化学 计算机科学 有机化学 光催化 嵌入式系统
作者
Xiaomin Chen,Ding Yuan,Chao Rong,Chao Wu,Porun Liu,Hua Kun Liu,Dingsheng Wang,Shi Xue Dou,Yuhai Dou
出处
期刊:Advanced powder materials [Elsevier BV]
卷期号:4 (5): 100330-100330 被引量:4
标识
DOI:10.1016/j.apmate.2025.100330
摘要

Single-atom catalysts (SACs) have demonstrated exceptional performance in electrocatalytic water splitting, owing to their maximized atomic utilization efficiency and superior reaction kinetics. The incorporation of SACs typically depends on robust metal-support interactions, which stabilize the single atoms on the support through various unsaturated chemical sites or spatial confinement. A critical challenge lies in precisely modulating the electronic structure and coordination environment of metal atoms. However, current research primarily focuses on single-atom metals, often neglecting the significant role of support materials in SACs. Two-dimensional (2D) atomically thin materials (ATMs) possess unique physicochemical properties and tunable reaction environments, which can modulate catalytic performance via metal-support interactions, positioning them as promising platforms for SAC loading. This paper reviews the recent advancements and the current status of SACs supported on 2D ATMs (SACs@ATMs). The structural design theory and synthesis strategies of SACs@ATMs are systematically discussed. The significance of advanced characterization techniques in elucidating the coordination environment and metal-support interactions is highlighted. Additionally, the reaction mechanisms and applications of SACs in electrocatalytic water splitting are summarized. Finally, the future challenges and opportunities for SACs@ATMs are outlined. This paper aims to provide insights and guidance for the rational design of SACs@ATMs with high-performance electrocatalytic water splitting capabilities. Single-atom catalysts (SACs) are highly efficient for splitting water into clean energy. This review explores how pairing SACs with 2D atomically-thin materials boosts their performance. It summarizes how these catalysts are designed and made, how scientists study their structure, and their role in water splitting. The analysis also outlines future challenges and opportunities for improving these advanced catalysts.
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