材料科学
氧化还原
流动电池
钒
催化作用
电化学
纳米技术
储能
电极
流量(数学)
单层
电流密度
化学工程
欧姆接触
功率密度
电池(电)
商业化
能量密度
电化学储能
镓
密度泛函理论
纳米材料基催化剂
过渡金属
电催化剂
燃烧
作者
Xiangyang Zhang,Walid A. Daoud,Ningxin Xiong,Agnes Valencia,Xian Yue,Jinsong Zhou,Fei Liu,Xingyi Shi,Lei Wei,Qixing Wu,Xuelong Zhou
标识
DOI:10.1002/adma.202520913
摘要
ABSTRACT Pursuing high‐power‐density all‐vanadium redox flow batteries (VRFBs) is an attractive approach toward large‐scale commercialization in a techno‐economic manner. The suboptimal intrinsic activity of conventional catalysts undermines flow batteries' inherent electrode design flexibility, restricting their current density to the low hundreds of mA cm −2 range and curtailing their technological viability. Here, for the first time, we present a few‐layer bismuthene nanoflake (Bi ene NF) catalyst in the field of redox flow batteries (RFBs). The design strategically exploits the ultra‐high intrinsic reactivity of Bi ene NF's outermost lattice periphery, including individual bismuthene monolayer edges where synergistic nanostructural effects and surface chemistry collectively enhance vanadium redox kinetics and thermodynamics. Notably, this edge‐activated catalytic mechanism demonstrates significant intrinsic activity enhancement over bulk bismuth, effectively addressing the dual challenges of deactivation and ohmic losses in flow battery systems. Accordingly, the fueled VRFB reaps an energy efficiency (EE) of up to 80.51% and a reliable catalyst stability over 10 000 cycles at 0.8 A cm −2 , together with an unprecedented peak power density of 3.047 W cm −2 . The demonstrated performance metrics not only establish new benchmarks for VRFB technology but also provide a generalizable strategy for designing high‐activity nanostructured catalysts in electrochemical energy storage systems.
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