钝化
光电流
分解水
氧化物
材料科学
联轴节(管道)
光电子学
氢
赤铁矿
硅
金属
密度泛函理论
调制(音乐)
化学物理
无机化学
化学工程
可逆氢电极
纳米技术
人工光合作用
电荷(物理)
工作(物理)
铱
电解质
中心(范畴论)
化学
表面电荷
图层(电子)
太阳能
电子结构
载流子
析氧
制氢
双层(生物学)
干扰(通信)
能量转换效率
光电化学电池
作者
Chao‐Qun Li,Nan Yang,Kepeng Song,Zhao‐Hua Yin,Long Chen,H. Gerard C. Tan,Fei‐Xue Tian,Zhiwen Chen,Hong Liu,Jian‐Jun Wang
标识
DOI:10.1002/anie.202524928
摘要
ABSTRACT The pursuit of efficient and stable photoelectrochemical water oxidation in acidic media is impeded by issues of severe photo‐corrosion and sluggish reaction kinetics. This study presents a novel dual‐modification approach for hematite (α‐Fe 2 O 3 ) photoanodes, incorporating an acid‐resistant silicon oxide (SiO x ) passivation layer and an interconnected iridium oxide (IrO x ) cocatalyst. The optimized Fe 2 O 3 ‐Si/Ir photoanode achieves a record photocurrent density of 2.32 mA cm −2 at 1.23 V RHE in acidic electrolyte, along with exceptional stability over 60 min, significantly surpassing all previously reported hematite‐based systems under acidic conditions. A key innovation lies in the multifunctional role of the SiO x overlayer, which not only passivates surface states to improve bulk charge separation but also promotes the formation of a uniform IrO x network and inhibits over‐oxidation of Ir to soluble high valent species (e.g., IrO 4 2– ). Combined experimental and theoretical evidence reveals strong electronic interaction at the Si–Ir interface, modulating the d‐band center of Ir, enhancing interfacial charge transfer, and reducing the Gibbs free energies of the rate‐determining step in water oxidation. This work establishes a synergistic materials design strategy for highly efficient and durable solar water splitting in acidic environments, offering a viable route toward practical solar hydrogen production.
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