Jiexin Zou scite author profile

Proton exchange membrane (PEM) water electrolysis is a promising energy storage solution by electrochemically splitting water into hydrogen fuel and oxygen. However, the sluggish kinetics, high operating potential, and corrosive acidic environment during the oxygen evolution reaction (OER) require the use of scarce and costly Ir-based oxides, tremendously hampering its large-scale commercialization. Hence, developing active and stable anode catalysts with reduced precious-metal usage is desperately essential. For the first time, we report a group of Y 2−x Ba x Ru 2 O 7 pyrochlore oxides and employ them in acid OER and PEM electrolyzers. We reveal the mechanism for the promoted OER performance of Ba-doped Y 2 Ru 2 O 7 in which partially replacing Y 3+ by Ba 2+ in Y 2 Ru 2 O 7 greatly facilitates the hole-doping effect, which generates massive oxygen vacancy and multivalence of Ru 5+ / Ru 4+ , thus boosting the OER performance of Y 2−x Ba x Ru 2 O 7 . This work provides an effective method and paradigm for improving the electrocatalytic property of pyrochlore oxides.

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Electrochemical Compression Technologies for High-Pressure Hydrogen: Current Status, Challenges and Perspective

Zou

Han

Yan

et al. 2020

Electrochem. Energ. Rev.

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Hydrogen is an ideal energy carrier in future applications due to clean byproducts and high efficiency. However, many challenges remain in the application of hydrogen, including hydrogen production, delivery, storage and conversion. In terms of hydrogen storage, two compression modes (mechanical and non-mechanical compressors) are generally used to increase volume density in which mechanical compressors with several classifications including reciprocating piston compressors, hydrogen diaphragm compressors and ionic liquid compressors produce significant noise and vibration and are expensive and inefficient. Alternatively, non-mechanical compressors are faced with issues involving large-volume requirements, slow reaction kinetics and the need for special thermal control systems, all of which limit large-scale development. As a result, modular, safe, inexpensive and efficient methods for hydrogen storage are urgently needed. And because electrochemical hydrogen compressors (EHCs) are modular, highly efficient and possess hydrogen purification functions with no moving parts, they are becoming increasingly prominent. Based on all of this and for the first time, this review will provide an overview of various hydrogen compression technologies and discuss corresponding structures, principles, advantages and limitations. This review will also comprehensively present the recent progress and existing issues of EHCs and future hydrogen compression techniques as well as corresponding containment membranes, catalysts, gas diffusion layers and flow fields. Furthermore, engineering perspectives are discussed to further enhance the performance of EHCs in terms of the thermal management, water management and the testing protocol of EHC stacks. Overall, the deeper understanding of potential relationships between performance and component design in EHCs as presented in this review can guide the future development of anticipated EHCs.

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Study of failure mechanisms of the reversal tolerant fuel cell anode via novel in-situ measurements

Wang

Zhou

Xie

et al. 2020

International Journal of Hydrogen Energy

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Jiexin Zou

Influence of Surface Oxygen Vacancies and Ruthenium Valence State on the Catalysis of Pyrochlore Oxides

Electrochemical Compression Technologies for High-Pressure Hydrogen: Current Status, Challenges and Perspective

Study of failure mechanisms of the reversal tolerant fuel cell anode via novel in-situ measurements

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