Dan Liu, Xuewen Xia, Xueqiang Zhang, Fei Wang, Li Tao, Ya Gao, Shujuan Wang, Zhongya Pang, Xing Yu, Guangshi Li, Hsien-Yi Hsu, Shen Hu, Li Ji, Xionggang Lu, Xingli Zou
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引用次数: 0
摘要
电催化剂的界面工程已被证明是调节电催化性能的有效方法,然而,要在大电流下促进氧进化反应(OER),迫切需要一种更有效、更直接的策略来构建有效的异质界面,以进一步增强界面效应。本文通过一步水热处理在原位形成了镍钴金属有机框架(MOF)和Ce-MOF的紧密致密异质结构,并采用部分磷化的方法进一步增强了泡沫镍上新形成的海胆状镍钴金属壳和六方棒状Ce-MOF芯之间的界面效应(NiCoP/Ce-MOF@NF)。实验和理论结果表明,异质的 NiCoP/Ce-MOF@NF 具有更密集的界面而不是简单的物理混合物的特点,它产生了有利于 OER 的电子结构,极大地促进了电荷转移和反应动力学,并形成了协同稳定的结构。最佳的 NiCoP/Ce-MOF@NF 对 OER 具有显著的电催化活性,在 500 mA cm-2 的电流密度下实现了 268 mV 的超低过电位,并具有令人满意的长达 120 小时的大电流稳定性。
Interface Engineering for Improved Large-Current Oxygen Evolution via Partial Phosphorization of Ce-MOF/NiCo-MOF Heterostructure
Interface engineering for electrocatalysts has proven to be an effective method for modulating electrocatalytic properties, yet a more efficient and straightforward strategy to construct a valid heterointerface for further enhancing interface effects is urgently needed for boosting oxygen evolution reactions (OER) at large current. Herein, a closely compacted heterostructure combining NiCo-metal-organic framework (MOF) and Ce-MOF is in situ formed through a one-step hydrothermal treatment, and partial phosphorization is employed to further enhance the interface effect between the newly formed urchin-shaped NiCoP shells and hexagonal rod-like Ce-MOF cores on nickel foam (NiCoP/Ce-MOF@NF). Experimental and theoretical results indicate that the heterogeneous NiCoP/Ce-MOF@NF, characterized by a more intensive interface rather than a simple physical mixture, generates an OER-beneficial electronic structure, significantly facilitates charge transfer and reaction kinetics, and creates a synergistically stable structure. The optimal NiCoP/Ce-MOF@NF exhibits remarkable electrocatalytic activity for OER, achieving an ultralow overpotential of 268 mV at a current density of 500 mA cm−2, and also delivers satisfactory large-current stability of up to 120 h. This work offers a novel approach for designing heterogeneous catalysts with strong interface effects for potential applications in industrial water electrolysis.
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Small serves as an exceptional platform for both experimental and theoretical studies in fundamental and applied interdisciplinary research at the nano- and microscale. The journal offers a compelling mix of peer-reviewed Research Articles, Reviews, Perspectives, and Comments.
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