物理化学学报 >> 2024, Vol. 40 >> Issue (1): 2303040.doi: 10.3866/PKU.WHXB202303040

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理论研究Cu@C2N催化剂表面上水分子对电催化CO2还原反应机理的影响

徐涵煜1, 宋雪旦1,*(), 张青1, 于畅1, 邱介山1,2,*()   

  1. 1 大连理工大学化工学院, 辽宁省能源材料化工重点实验室, 精细化工国家重点实验室, 辽宁 大连 116024
    2 北京化工大学化学工程学院, 有机无机复合材料国家重点实验室, 化工资源有效利用国家重点实验室, 北京 100029
  • 收稿日期:2023-03-20 录用日期:2023-05-08 发布日期:2023-08-21
  • 通讯作者: 宋雪旦,邱介山 E-mail:song@dlut.edu.cn;jqiu@dlut.edu.cn
  • 基金资助:
    国家自然科学基金(22078052);中央高校基本科研业务费专项资金(DUT22ZD207)

Mechanistic Insights into Water-Mediated CO2 Electrochemical Reduction Reactions on Cu@C2N Catalysts: A Theoretical Study

Hanyu Xu1, Xuedan Song1,*(), Qing Zhang1, Chang Yu1, Jieshan Qiu1,2,*()   

  1. 1 Liaoning Key Lab for Energy Materials and Chemical Engineering, State Key Laboratory of Fine Chemicals, School of Chemical Engineering, Dalian University of Technology, Dalian 116024, Liaoning Province, China
    2 State Key Laboratory of Organic-Inorganic Composites, State Key Laboratory of Chemical Resource Engineering, College of Chemical Engineering, Beijing University of Chemical Technology, Beijing 100029, China
  • Received:2023-03-20 Accepted:2023-05-08 Published:2023-08-21
  • Contact: Xuedan Song, Jieshan Qiu E-mail:song@dlut.edu.cn;jqiu@dlut.edu.cn
  • Supported by:
    the National Natural Science Foundation of China(22078052);the Fundamental Research Funds for the Central Universities, China(DUT22ZD207)

摘要:

电催化CO2还原反应(CO2RR)的反应途径涉及多个质子-电子对转移,在水溶剂条件下,质子的来源是水分子,考虑水分子对质子-电子对的转移机制十分必要。本研究提出水辅助氢穿梭模型,与常用的以氢原子作为氢源的直接加氢模型对比,研究水分子在CO2RR中对质子-电子对转移的影响。采用密度泛函理论,系统地研究了铜原子嵌入C2N单层催化剂(Cu@C2N)和石墨烯作为衬底的Cu@C2N/石墨烯复合催化剂(Cu@C2N/G)表面上不同加氢模型的CO2RR反应机理。在水辅助氢穿梭模型中,氢原子与水分子结合形成水合质子,水合质子将自身的氢原子转移到催化剂表面的反应物上形成反应中间体,增强了中间体与催化剂之间的相互作用。此外,在Cu@C2N/G催化剂中,石墨烯将电子转移到表面的Cu@C2N上,提高了催化剂的CO2RR催化活性。进一步,计算了Cu@C2N和Cu@C2N/G催化剂上CO2RR和析氢反应的极限电位,讨论催化剂的活性和选择性。结果表明CO2在低电位下容易生成HCOOH,施加高电位时可以生成CO、CH3OH和CH4并伴随着H2的生成。

关键词: CO2还原反应, 电催化, 氮掺杂石墨烯, 水辅助氢穿梭, 反应机理, 密度泛函理论

Abstract:

CO2 molecules can be converted into various fuels and industrial chemicals through electrochemical reduction, effectively addressing the problems of global warming, desertification, ocean acidification, and other adverse environmental changes and energy supply issues such as excessive utilization of nonrenewable fossil fuels. Generally, the pathway of the CO2 reduction reaction (CO2RR) involves multiple proton–electron pairs transferred to the reactants, resulting in the production of multiple reduction products. Here, protons are derived from water molecules under aqueous solvent conditions. Therefore, exploring the effect of water molecules on the proton–electron pair transfer process in CO2RRs is essential. In this study, we developed a water-mediated hydrogen shuttle model (H-shuttling) as a hydrogenation model to investigate the effect of water molecules on the proton–electron pair transfer process in CO2RRs and compared it with the widely used water-free direct hydrogenation model (H-transfer), wherein the hydrogen atom is used as a proton. Because copper is a metal electrode material capable of producing hydrocarbons from CO2 electroreduction with a high faraday efficiency, and nitrogen-doped graphene (C2N) exhibits excellent catalytic CO2 activation, we selected a single copper atom-embedded C2N (Cu@C2N) as the catalyst. Furthermore, to study the effect of graphene on the CO2RR activity of Cu@C2N/G, we selected a graphene-loaded Cu@C2N composite (Cu@C2N/G) as the catalyst because graphene was utilized as a substrate to boost the conductivity of the catalyst. In the two hydrogenation models, we investigated the mechanisms of CO2RRs on Cu@C2N and Cu@C2N/G catalysts through density functional theory calculations. Notably, in the H-shuttling model, the H atom combines with the water molecule to form H3O, which transfers one of its own H atoms to a reactant on the catalyst surface, yielding a reaction intermediate. The H-shuttling model enhances the interaction between the catalyst and intermediate. Graphene, as a substrate, transfers electrons to the Cu@C2N surface of the Cu@C2N/G catalyst, which is demonstrated by calculations of the Bader charge transferred between the reaction intermediate and catalyst, as well as the Gibbs free energy of the CO2 reduction elementary reaction. This effectively lowers the Gibbs free energy of the potential-determining step and enhances the CO2RR catalytic activity of Cu@C2N/G. Moreover the limiting potentials of the CO2RR and hydrogen evolution reaction are determined to obtain the activity and selectivity of the Cu@C2N and Cu@C2N/G catalysts. The results indicate that CO2 molecules on the Cu@C2N and Cu@C2N/G catalysts generate HCOOH at low applied potentials, and are able to produce CO, CH3OH, CH4, and H2 as the applied potentials increases.

Key words: CO2 reduction reaction, Electrocatalysis, Nitrogen-doped graphene, Water-mediated hydrogen shuttle, Reaction mechanism, Density functional theory