过电位
氧气
无定形固体
材料科学
化学工程
浸出(土壤学)
析氧
催化作用
再分配(选举)
化学
共价键
活动站点
无机化学
无定形碳
氧化还原
电解水
分解水
活性氧
热稳定性
纳米技术
作者
Zhenlong Wang,Jing Li,Cong Li,Gao-Yuan Huang,Chun-Chao Chen,Hai-Bin Zhu
标识
DOI:10.1021/acssuschemeng.5c10744
摘要
To address the imbalance issue between the water oxidation activity and stability of catalysts via the lattice oxygen oxidation mechanism (LOM), this study reports the rational design of an amorphous high-entropy catalyst (HEB-CTS) for efficient water oxidation. HEB-CTS is characterized by multielement synergy, intrinsic amorphous structure, and abundant oxygen vacancies. The oxygen vacancies resulting through the carbon thermal shock (CTS) technique inhibit excessive leaching of alkali-soluble elements (Mo, Zn) in HEB-CTS, which mitigates the loss of active components caused by excessive surface reconstruction. Density function calculation reveals that the p-orbitals of oxygen on the reconstructed catalyst surface exhibit stronger hybridization with the d-orbitals of active elements (Ni, Co), thus enhancing the covalent M–O bonding and promoting direct O–O coupling of lattice oxygen to generate O2 via LOM. Additionally, the charge redistribution between the reconstructed active MOOH layer and the bulk HEB-CTS facilitates the rapid replenishment of surface OH–. Under such a design, HEB-CTS achieves an overpotential of only 250 mV at 10 mA cm–2 and maintains stable water oxidation for over 550 h at 100 mA cm–2, significantly outperforming commercial RuO2 and some reported high-entropy benchmark materials. This study provides a novel strategy for developing highly efficient and stable LOM-based high-entropy amorphous catalysts for water oxidation.
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