在基底上电化学合成具有三维结构的缺陷硒化铟用于将一氧化碳电还原为合成气的可调谐过程

Electrosynthesis of a Defective Indium Selenide with 3D Structure on a Substrate for Tunable CO Electroreduction to Syngas.

作者信息

Yang Dexin, Zhu Qinggong, Sun Xiaofu, Chen Chunjun, Guo Weiwei, Yang Guanying, Han Buxing

机构信息

Beijing National Laboratory for Molecular Sciences, Key Laboratory of Colloid and Interface and Thermodynamics, Institute of Chemistry, Chinese Academy of Sciences, Beijing, 100190, China.

University of Chinese Academy of Sciences, Beijing, 100049, China.

出版信息

Angew Chem Int Ed Engl. 2020 Feb 3;59(6):2354-2359. doi: 10.1002/anie.201914831. Epub 2019 Dec 19.

DOI:10.1002/anie.201914831

PMID:31797503

Abstract

Syngas (CO/H ) is a feedstock for the production of a variety of valuable chemicals and liquid fuels, and CO electrochemical reduction to syngas is very promising. However, the production of syngas with high efficiency is difficult. Herein, we show that defective indium selenide synthesized by an electrosynthesis method on carbon paper (γ-In Se /CP) is an extremely efficient electrocatalyst for this reaction. CO and H were the only products and the CO/H ratio could be tuned in a wide range by changing the applied potential or the composition of the electrolyte. In particular, using nanoflower-like γ-In Se /CP (F-γ-In Se /CP) as the electrode, the current density could be as high as 90.1 mA cm at a CO/H ratio of 1:1. In addition, the Faradaic efficiency of CO could reach 96.5 % with a current density of 55.3 mA cm at a very low overpotential of 220 mV. The outstanding electrocatalytic performance of F-γ-In Se /CP can be attributed to its defect-rich 3D structure and good contact with the CP substrate.

摘要

合成气（CO/H₂）是用于生产各种有价值化学品和液体燃料的原料，通过电化学方法将CO还原为合成气很有前景。然而，高效生产合成气具有挑战性。在此，我们展示了通过电合成方法在碳纸上合成的缺陷硒化铟（γ-In₂Se₃/CP）是该反应的一种极其高效的电催化剂。CO和H₂是仅有的产物，并且通过改变施加的电势或电解液的组成，CO/H₂比率可在很宽的范围内调节。特别地，使用纳米花状的γ-In₂Se₃/CP（F-γ-In₂Se₃/CP）作为电极，在CO/H₂比率为1:1时，电流密度可高达90.1 mA cm⁻²。此外，在220 mV的极低过电势下，CO的法拉第效率在电流密度为55.3 mA cm⁻²时可达到96.5%。F-γ-In₂Se₃/CP出色的电催化性能可归因于其富含缺陷的三维结构以及与CP基底的良好接触。

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在基底上电化学合成具有三维结构的缺陷硒化铟用于将一氧化碳电还原为合成气的可调谐过程

Electrosynthesis of a Defective Indium Selenide with 3D Structure on a Substrate for Tunable CO Electroreduction to Syngas.

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