Bimetal Schottky Heterojunction Boosting Energy-Saving Hydrogen Production from Alkaline Water via Urea Electrocatalysis

Wang Chao; Lu Haoliang; Mao Zeyang; Yan Chenglin; Shen Guozhen; Wang Xianfu

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Bimetal Schottky Heterojunction Boosting Energy-Saving Hydrogen Production from Alkaline Water via Urea Electrocatalysis

机译：双金属肖特基异质通信通过尿素电催化从碱性水促进节能氢气生产

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摘要

Hydrogen production via water electrocatalysis is limited by the sluggish anodic oxygen evolution reaction (OER) that requires a high overpotential. In response, a urea-assisted energy-saving alkaline hydrogen-production system has been investigated by replacing OER with a more oxidizable urea oxidation reaction (UOR). A bimetal heterostructure CoMn/CoMn2O4 as a bifunctional catalyst is constructed in an alkaline system for both urea oxidation and hydrogen evolution reaction (HER). Based on the Schottky heterojunction structure, CoMn/CoMn2O4 induces self-driven charge transfer at the interface, which facilitates the absorption of reactant molecules and the fracture of chemical bonds, therefore triggering the decomposition of water and urea. As a result, the heterostructured electrode exhibits ultralow potentials of -0.069 and 1.32 V (vs reversible hydrogen electrode) to reach 10 mA cm(-2) for HER and UOR, respectively, in alkaline solution, and the full urea electrolysis driven by CoMn/CoMn2O4 delivers 10 mA cm(-2) at a relatively low potential of 1.51 V and performs stably for more than 15 h. This represents a novel strategy of Mott-Schottky hybrids in electrocatalysts and should inspire the development of sustainable energy conversion by combining hydrogen production and sewage treatment.

机译：通过水电子分析的氢气产生受到需要高过电位的缓慢阳极氧气进化反应（OER）的限制。作为响应，通过用更可氧化的尿素氧化反应（UOR）替代OER来研究尿素辅助节能碱性氢气生产系统。作为双官能催化剂的双金属异质结构COMN / COMN2O4构建为尿素氧化和氢进化反应（她）的碱性系统中。基于肖特基异质结结构，COMN / COMN2O4在界面处诱导自驱动电荷转移，这有利于反应物分子的吸收和化学键的骨折，从而引发水和尿素的分解。结果，异质结构化电极显示出-0.069和1.32V（Vs可逆氢电极）的超级电位，分别在碱性溶液中达到10 mAcm（-2），以及由COMN驱动的全尿素电解/ COMN2O4以1.51V的相对低电位提供10 mA cm（-2），并稳定地执行超过15小时。这代表了电催化剂中Mott-Schottky杂交种的新型策略，并通过组合氢气产生和污水处理来激发可持续能量转换的发展。

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来源
《Advanced Functional Materials》 |2020年第21期|2000556.1-2000556.10|共10页
作者
Wang Chao; Lu Haoliang; Mao Zeyang; Yan Chenglin; Shen Guozhen; Wang Xianfu;
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作者单位

Soochow Univ Coll Energy Soochow Inst Energy & Mat Innovat Suzhou 215006 Peoples R China|Soochow Univ Jiangsu Prov Key Lab Adv Carbon Mat & Wearable En Suzhou 215006 Peoples R China|Soochow Univ Collaborat Innovat Ctr Suzhou Nano Sci & Technol Suzhou 215006 Peoples R China;

Soochow Univ Coll Energy Soochow Inst Energy & Mat Innovat Suzhou 215006 Peoples R China|Soochow Univ Jiangsu Prov Key Lab Adv Carbon Mat & Wearable En Suzhou 215006 Peoples R China|Soochow Univ Collaborat Innovat Ctr Suzhou Nano Sci & Technol Suzhou 215006 Peoples R China;

Soochow Univ Coll Energy Soochow Inst Energy & Mat Innovat Suzhou 215006 Peoples R China|Soochow Univ Jiangsu Prov Key Lab Adv Carbon Mat & Wearable En Suzhou 215006 Peoples R China|Soochow Univ Collaborat Innovat Ctr Suzhou Nano Sci & Technol Suzhou 215006 Peoples R China;

Soochow Univ Coll Energy Soochow Inst Energy & Mat Innovat Suzhou 215006 Peoples R China|Soochow Univ Jiangsu Prov Key Lab Adv Carbon Mat & Wearable En Suzhou 215006 Peoples R China|Soochow Univ Collaborat Innovat Ctr Suzhou Nano Sci & Technol Suzhou 215006 Peoples R China;

Chinese Acad Sci Inst Semicond State Key Lab Superlattices & Microstruct Beijing 100083 Peoples R China;

Soochow Univ Coll Energy Soochow Inst Energy & Mat Innovat Suzhou 215006 Peoples R China|Soochow Univ Jiangsu Prov Key Lab Adv Carbon Mat & Wearable En Suzhou 215006 Peoples R China|Soochow Univ Collaborat Innovat Ctr Suzhou Nano Sci & Technol Suzhou 215006 Peoples R China;

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正文语种 eng
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bimetal catalysis; electrochemical turning; hydrogen evolution; Schottky heterojunctions; urea oxidation;

机译：双金属催化;电化学转动;氢气进化;肖特基异血;尿素氧化;

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1. Nitrogen-rich g-C3N4@AgPd Mott-Schottky heterojunction boosts photocatalytic hydrogen production from water and tandem reduction of NO3- and NO2- [J] . Liu Xinyang, Liu Hu, Wang Yingjun, Journal of Colloid and Interface Science . 2021,第Pta2期

机译：富含氮的G-C3N4 @ AGPD Mott-Schottky异质结促进了从水中的光催化氢气产生，串联减少NO3和NO2-
2. Oxygen-Incorporated NiMoP Nanotube Arrays as Efficient Bifunctional Electrocatalysts For Urea-Assisted Energy-Saving Hydrogen Production in Alkaline Electrolyte [J] . Jiang Hao, Sun Mingzi, Wu Shuilin, Advanced Functional Materials . 2021,第43期

机译：氧气掺入的尼莫纳米管阵列作为碱性电解质尿素辅助节能氢生产的有效双官能电催化剂
3. Construction of CdS@Ti3C2@CoO hierarchical tandem p-n heterojunction for boosting photocatalytic hydrogen production in pure water [J] . Chemical engineering journal . 2020,第期

机译：CDS @ Ti3C2 @ CoO分层串联P-N异质结的构建，用于促进纯水中的光催化氢气
4. NITROGEN-ENRICHED CARBON WITH ENCAPSULATED NICKEL NANOPARTICLES FOR HYDROGEN EVOLUTION ELECTROCATALYSIS IN ALKALINE ELECTROLYTES [C] . Zhi-Yu Yang, Qinghua Liang, Xiaoliang Yu World Conference on Carbon . 2016

机译：富含氮碳的含氮镍纳米粒子，用于碱性电解质中的氢进化电催化
5. Improving electrochemical methods of producing hydrogen in alkaline media via ammonia and urea electrolysis. [D] . Boggs, Bryan Kenneth. 2010

机译：改进了通过氨和尿素电解在碱性介质中生产氢的电化学方法。
6. Overproduction of the cyanobacterial hydrogenase and selection of a mutant thriving on urea, as a possible step towards the future production of hydrogen coupled with water treatment [O] . Théo Veaudor, Marcia Ortega-Ramos, Thichakorn Jittawuttipoka, 2012

机译：蓝藻加氢酶的过量生产和尿素上突变型突变体的选择，这可能是未来生产氢气和水处理的可能步骤
7. Hydrogen Evolution Reaction: Synergistically Tuning Water and Hydrogen Binding Abilities Over Co 4 N by Cr Doping for Exceptional Alkaline Hydrogen Evolution Electrocatalysis (Adv. Energy Mater. 41/2019) [O] . Na Yao, Peng Li, Zirui Zhou, 2019

机译：氢进化反应：CR掺杂对卓越碱性氢进化电催化的CR掺杂（ADV。能量母体41/2019）的氢气进化反应：通过CR掺杂进行协同调整水和氢结合能力
8. Electrocatalysis of Oxygen Reduction. Part III. Selective Reduction to Hydrogen Peroxide or Water Using Polymeric Attachment of Metalloporphyrins [R] . Bettelheim, A., Chan, R. J. H., Kuwana, T. 1979

机译：氧还原的电催化。第三部分。使用金属卟啉的聚合物连接选择性还原为过氧化氢或水

Bimetal Schottky Heterojunction Boosting Energy-Saving Hydrogen Production from Alkaline Water via Urea Electrocatalysis

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