Ren Shaoxuan, Zhang Zishuai, Lees Eric W, Fink Arthur G, Melo Luke, Hunt Camden, Dvorak David J, Yu Wu Wen, Grant Edward R, Berlinguette Curtis P
Department of Chemistry, The University of British Columbia, 2036 Main Mall, Vancouver, British Columbia, V6T 1Z1, Canada.
Department of Chemical and Biological Engineering, The University of British Columbia, 2355 East Mall, Vancouver, British Columbia, V6T 1Z3, Canada.
Chemistry. 2022 May 2;28(25):e202200340. doi: 10.1002/chem.202200340. Epub 2022 Mar 28.
Electrochemical reactors that electrolytically convert CO into higher-value chemicals and fuels often pass a concentrated hydroxide electrolyte across the cathode. This strongly alkaline medium converts the majority of CO into unreactive HCO and CO byproducts rather than into CO reduction reaction (CO2RR) products. The electrolysis of CO (instead of CO ) does not suffer from this undesirable reaction chemistry because CO does not react with OH . Moreover, CO can be more readily reduced into products containing two or more carbon atoms (i. e., C products) compared to CO . We demonstrate here that an electrocatalyst layer derived from copper phthalocyanine (CuPc) mediates this conversion effectively in a flow cell. This catalyst achieved a 25 % higher selectivity for acetate formation at 200 mA/cm than a known state-of-art oxide-derived Cu catalyst tested in the same flow cell. A gas diffusion electrode coated with CuPc electrolyzed CO into C products at high rates of product formation (i. e., current densities ≥200 mA/cm ), and at high faradaic efficiencies for C production (FE ; >70 % at 200 mA/cm ). While operando Raman spectroscopy did not reveal evidence of structural changes to the copper molecular complex, X-ray photoelectron spectroscopy suggests that the catalyst undergoes conversion to a metallic copper species during catalysis. Notwithstanding, the ligand environment about the metal still impacts catalysis, which we demonstrated through the study of a homologous CuPc bearing ethoxy substituents. These findings reveal new strategies for using metal complexes for the formation of carbon-neutral chemicals and fuels at industrially relevant conditions.
将CO电解转化为高价值化学品和燃料的电化学反应器通常会使浓缩的氢氧化物电解质通过阴极。这种强碱性介质会将大部分CO转化为无反应性的HCO和CO副产物,而不是转化为CO还原反应(CO2RR)产物。CO的电解(而不是CO的电解)不会受到这种不良反应化学的影响,因为CO不与OH反应。此外,与CO相比,CO可以更容易地还原为含有两个或更多碳原子的产物(即C产物)。我们在此证明,由铜酞菁(CuPc)衍生的电催化剂层在流动池中有效地介导了这种转化。在相同的流动池中测试时,这种催化剂在200 mA/cm²的电流密度下对乙酸盐形成的选择性比已知的最先进的氧化物衍生铜催化剂高25%。涂有CuPc的气体扩散电极以高的产物形成速率(即电流密度≥200 mA/cm²)和高的C产物法拉第效率(FE;在200 mA/cm²时>70%)将CO电解为C产物。虽然原位拉曼光谱没有揭示铜分子络合物结构变化的证据,但X射线光电子能谱表明催化剂在催化过程中会转化为金属铜物种。尽管如此,金属周围的配体环境仍然会影响催化作用,我们通过对带有乙氧基取代基的同源CuPc的研究证明了这一点。这些发现揭示了在工业相关条件下使用金属络合物形成碳中性化学品和燃料的新策略。
