Optimizing oxygen vacancies through grain boundary engineering to enhance electrocatalytic nitrogen reduction

被引:46
|
作者
Zhong, Xiu [1 ]
Yuan, Enxian [2 ]
Yang, Fu [1 ]
Liu, Yang [1 ]
Lu, Hao [1 ]
Yang, Jun [3 ]
Gao, Fei [1 ]
Zhou, Yu [4 ]
Pan, Jianming [5 ]
Zhu, Jiawei [6 ]
Yu, Chao [1 ]
Zhu, Chengzhang [7 ]
Yuan, Aihua [1 ]
Ang, Edison Huixiang [8 ]
机构
[1] Jiangsu Univ Sci & Technol, Sch Environm & Chem Engn, Zhenjiang 212100, Jiangsu, Peoples R China
[2] Yangzhou Univ, Sch Chem & Chem Engn, Yangzhou 225002, Jiangsu, Peoples R China
[3] Jiangsu Univ Sci & Technol, Sch Mat Sci & Engn, Zhenjiang 212100, Jiangsu, Peoples R China
[4] Nanjing Tech Univ, Coll Chem Engn, State Key Lab Mat Oriented Chem Engn, Nanjing 211816, Peoples R China
[5] Jiangsu Univ, Sch Chem & Chem Engn, Zhenjiang 212013, Jiangsu, Peoples R China
[6] Chinese Acad Sci, Qingdao Inst Bioenergy & Bioproc Technol, Qingdao 266101, Peoples R China
[7] Nanjing Tech Univ, Sch Environm Sci & Engn, Nanjing 211816, Peoples R China
[8] Nanyang Technol Univ, Natl Inst Educ, Nat Sci & Sci Educ, Singapore 637616, Singapore
来源
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA | 2023年 / 120卷 / 40期
基金
中国国家自然科学基金;
关键词
grain boundaries; oxygen vacancy; ammonia synthesis; nitrogen reduction; electrocatalyst; AMBIENT CONDITIONS; N-2; REDUCTION; FIXATION; EFFICIENT; AMMONIA; NANOSHEETS; NANORODS; MXENE;
D O I
10.1073/pnas.2306673120
中图分类号
O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];
学科分类号
07 ; 0710 ; 09 ;
摘要
Electrocatalytic nitrogen reduction is a challenging process that requires achieving high ammonia yield rate and reasonable faradaic efficiency. To address this issue, this study developed a catalyst by in situ anchoring interfacial intergrown ultrafine MoO2 nanograins on N-doped carbon fibers. By optimizing the thermal treatment conditions, an abundant number of grain boundaries were generated between MoO2 nanograins, which led to an increased fraction of oxygen vacancies. This, in turn, improved the transfer of electrons, resulting in the creation of highly active reactive sites and efficient nitrogen trapping. The resulting optimal catalyst, MoO2/C700, outperformed commercial MoO2 and state-of-the-art N-2 reduction catalysts, with NH3 yield and Faradic efficiency of 173.7 mu g h(-1)mg(-1)cat and 27.6%, respectively, under- 0.7 V vs. RHE in 1 M KOH electrolyte. In situ X-ray photoelectron spectroscopy characterization and density functional theory calculation validated the electronic structure effect and advantage of N-2 adsorption over oxygen vacancy, revealing the dominant interplay of N-2 and oxygen vacancy and generating electronic transfer between nitrogen and Mo(IV). The study also unveiled the origin of improved activity by correlating with the interfacial effect, demonstrating the big potential for practical N-2 reduction applications as the obtained optimal catalyst exhibited appreciable catalytic stability during 60 h of continuous electrolysis. This work demonstrates the feasibility of enhancing electrocatalytic nitrogen reduction by engineering grain boundaries to promote oxygen vacancies, offering a promising avenue for efficient and sustainable ammonia production.
引用
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页数:9
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