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Designing Efficient Nitrate Reduction Electrocatalysts by Identifying and Optimizing Active Sites of Co-Based Spinels

Qi Hu, Shuai Qi, Qihua Huo, Yuxin Zhao, Jianju Sun, Xinbao Chen, Miaoyuan Lv, Weiliang Zhou, Chao Feng, Xiaoyan Chai, Hengpan Yang, Chuanxin He

2023Journal of the American Chemical Society256 citationsDOI

Abstract

Cobalt-based spinel oxides (i.e., Co 3 O 4 ) are emerging as low-cost and selective electrocatalysts for the electrochemical nitrate reduction reaction (NO 3 – RR) to ammonia (NH 3 ), although their activity is still unsatisfactory and the genuine active site is unclear. Here, we discover that the NO 3 – RR activity of Co 3 O 4 is highly dependent on the geometric location of the Co site, and the NO 3 – RR prefers to occur at octahedral Co (Co Oh ) rather than tetrahedral Co (Co Td ) sites. Moreover, Co Oh O 6 is electrochemically transformed to Co Oh O 5 along with the formation of O vacancies (O v ) during the process of NO 3 – RR. Both experimental and theoretic results reveal that in situ generated Co Oh O 5 –O v configuration is the genuine active site for the NO 3 – RR. To further enhance the activity of Co Oh sites, we replace inert Co Td with different contents of Cu 2+ cations, and a volcano-shape correlation between NO 3 – RR activity and electronic structures of Co Oh is observed. Impressively, in 1.0 M KOH, (Cu 0.6 Co 0.4 )Co 2 O 4 with optimized Co Oh sites achieves a maximum NH 3 Faradaic efficiency of 96.5% with an ultrahigh NH 3 rate of 1.09 mmol h –1 cm –2 at −0.45 V vs reversible hydrogen electrode, outperforming most of other reported nonprecious metal-based electrocatalysts. Clearly, this work paves new pathways for boosting the NO 3 – RR activity of Co-based spinels by tuning local electronic structures of Co Oh sites.

Topics & Concepts

ChemistryReduction (mathematics)NitrateCombinatorial chemistryInorganic chemistryOrganic chemistryGeometryMathematicsAmmonia Synthesis and Nitrogen ReductionCaching and Content DeliveryAdvanced Photocatalysis Techniques
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