Superior performance of anion exchange membrane water electrolyzer: Ensemble of producing oxygen vacancies and controlling mass transfer resistance

Park Yoo Sei; Yang Juchan; Lee Jongmin; Jang Myeong Je; Jeong Jaehoon; Choi Woo-Sung; Kim Yangdo; Yin Yadong; Seo Min Ho; Chen Zhongwei; Choi Sung Mook

首页> 外文期刊>Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications >Superior performance of anion exchange membrane water electrolyzer: Ensemble of producing oxygen vacancies and controlling mass transfer resistance

【24h】

Superior performance of anion exchange membrane water electrolyzer: Ensemble of producing oxygen vacancies and controlling mass transfer resistance

机译：阴离子交换膜水电解器的卓越性能：生产氧空位的合奏和控制传质阻力

获取原文

获取原文并翻译 | 示例

掌桥外文数据库（机构版） >>

开具论文收录证明 >>

文献代查 >>

页面导航

摘要
著录项
相似文献
相关主题

摘要

A chemically etched CuCo-oxide (CE-CCO) electrode prepared by electrodeposition was used for oxygen evolution reaction electrocatalyst. Surface chemical etching of CuCo-oxide (CCO) introduced oxygen vacancies and thus increased electrical conductivity to promote oxygen generation. During practical applicability testing, when CE-CCO was used as the anode of an anion-exchange membrane water electrolyzer, enhanced oxygen evolution performance was observed (current density = 1390 mA/cm(2) at 1.8 V-cell), which, among other reactions, was ascribed to the easy removal of O-2 from the aerophobic electrode surface. In addition to featuring low mass transfer resistance even at high current density with substantial gas generation, the CE-CCO electrode featured remarkable durability, exhibiting stable performance over 3600 h under the conditions of continuous O-2 evolution. Thus, this work shows that the performance of electrodeposited oxide catalysts can be enhanced by introducing oxygen vacancies, while the energy conversion efficiency of the corresponding water electrolysis systems can be increased by lowering mass transfer resistance via efficient gas removal and reactant supply.

机译：通过电沉积制备的化学蚀刻的氧化甘油（CE-CCO）电极用于氧进化反应电催化剂。氧化铝（CCO）的表面化学蚀刻引入了氧空位，从而提高了导电性以促进氧气产生。在实际适用性测试期间，当使用CE-CCO作为阴离子交换膜水电解器的阳极时，观察到增强的氧气进化性能（电流密度= 1390mA / cm（2），其中1.8V细胞），其中其他反应归因于易于除去瓦斯波奇电极表面的O-2。除了具有低电流密度的低传质电阻外，CE-CCO电极具有显着的耐用性，在连续O-2进化的条件下，在3600小时内表现出稳定的性能。因此，该工作表明，通过引入氧空位可以提高电沉积氧化氧化物催化剂的性能，而通过有效的气体去除和反应物供应降低传质电阻，可以提高相应的水电解系统的能量转换效率。

著录项

来源
《Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications》 |2020年第1期|共12页
作者
Park Yoo Sei; Yang Juchan; Lee Jongmin; Jang Myeong Je; Jeong Jaehoon; Choi Woo-Sung; Kim Yangdo; Yin Yadong; Seo Min Ho; Chen Zhongwei; Choi Sung Mook;
展开▼
作者单位

Korea Inst Mat Sci Mat Ctr Energy Dept Surface Technol Div Chang Won 642831 South Korea;

Korea Inst Mat Sci Mat Ctr Energy Dept Surface Technol Div Chang Won 642831 South Korea;

Korea Inst Energy Res Fuel Cell Res &

Demonstrat Ctr Future Energy Res Div Buan Gun 56332 South Korea;

Korea Inst Mat Sci Mat Ctr Energy Dept Surface Technol Div Chang Won 642831 South Korea;

Korea Inst Mat Sci Mat Ctr Energy Dept Surface Technol Div Chang Won 642831 South Korea;

Korea Inst Mat Sci Mat Ctr Energy Dept Surface Technol Div Chang Won 642831 South Korea;

Pusan Natl Univ Dept Mat Sci &

Engn Busan 46241 South Korea;

Univ Calif Riverside Mat Sci &

Engn Program Dept Chem Riverside CA 92521 USA;

Korea Inst Energy Res Fuel Cell Res &

Demonstrat Ctr Future Energy Res Div Buan Gun 56332 South Korea;

Univ Waterloo Dept Chem Engn Waterloo ON N2L 3G1 Canada;

Korea Inst Mat Sci Mat Ctr Energy Dept Surface Technol Div Chang Won 642831 South Korea;

展开▼
收录信息
原文格式 PDF
正文语种 eng
中图分类催化;
关键词
Electrocatalyst; Oxygen vacancy; Oxygen evolution; Hydrogen energy; Anion exchange membrane water electrolysis;

机译：电催化剂;氧气空位;氧气进化;氢能;阴离子交换膜水电解;

相似文献

外文文献
中文文献
专利

1. Superior performance of anion exchange membrane water electrolyzer: Ensemble of producing oxygen vacancies and controlling mass transfer resistance [J] . Park Yoo Sei, Yang Juchan, Lee Jongmin, Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications . 2020,第1期

机译：阴离子交换膜水电解器的卓越性能：生产氧空位的合奏和控制传质阻力
2. Oxygen vacancy engineering of yttrium ruthenate pyrochlores as an efficient oxygen catalyst for both proton exchange membrane water electrolyzers and rechargeable zinc-air batteries [J] . Feng Qi, Zhao Zhiliang, Yuan Xiao-Zi, Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications . 2020,第期

机译：YTTRIUM氧化钇钌氧化钇的氧气空位工程作为质子交换膜水电解器和可充电锌空气电池的高效氧气催化剂
3. Synthesis and Characterization of the Cu_(0.72)Co_(2.28)O_4 Catalyst for Oxygen Evolution Reaction in an Anion Exchange Membrane Water Electrolyzer [J] . Sung Min Park, Myeong Je Jang, Yoo Sei Park Journal of Korean Institute of Metal and Materials . 2020,第1期

机译：阴离子交换膜水电解仪中氧进化反应的Cu_（0.72）CO_（2.28）O_4催化剂的合成与表征
4. Using Ion Exchange Capacity to Control Water Uptake in Electrodes of Low-Temperature Anion Exchange Membrane Electrolyzers [C] . Garrett Huang, Mrinmay Mandal, Alexandra Dobbs, Pacific Rim Meeting on Electrochemical and Solid-State Science . 2020

机译：采用离子交换能力控制低温阴离子交换膜电解器电极采水量
5. Non-Precious Metal Based Electrocatalysts for Oxygen Reduction in Proton Exchange Membrane Fuel Cells and Electrolyzers. [D] . Tylus, Urszula B. 2014

机译：用于质子交换膜燃料电池和电解槽中氧气还原的非贵金属基电催化剂。
6. Radiation-Grafted Anion-Exchange Membrane for Fuel Cell and Electrolyzer Applications: A Mini Review [O] . Kean Long Lim, Chun Yik Wong, Wai Yin Wong, 2021

机译：用于燃料电池和电解柜应用的辐射接枝阴离子交换膜：迷你评论
7. Synthesis and Characterization of the Cu_0.72Co_2.28O₄ Catalyst for Oxygen Evolution Reaction in an Anion Exchange Membrane Water Electrolyzer [O] . Sung Min Park, Myeong Je Jang, Yoo Sei Park, 2020

机译：Cu _{0.72 Co _{2.28 O _{4 催化剂在阴离子交换膜水电解仪中的氧进化反应中的合成与表征}}}
8. Hydrogen-oxygen proton-exchange membrane fuel cells and electrolyzers [R] . Baldwin, R., Pham, M., Leonida, A., 1989

机译：氢氧质子交换膜燃料电池和电解槽

Superior performance of anion exchange membrane water electrolyzer: Ensemble of producing oxygen vacancies and controlling mass transfer resistance

摘要

著录项

相似文献

相关主题

期刊订阅