Dynamic valence engineering of CuOx catalysts for selective and stable CO2 electroreduction to ethylene and ethanol
Huiting Huang, Jia Tian, Mingkun Jiang, Dan Wu
Abstract
Cu-based oxide (CuO x ) catalysts have emerged as promising candidates for electrochemical CO 2 reduction to C 2 products such as ethylene (C 2 H 4 ) and ethanol (C 2 H 5 OH). However, the simultaneous realization of high selectivity and long-term stability remains a critical challenge. This review systematically summarizes the fundamental mechanisms governing C–C coupling on CuO x catalysts, emphasizing the role of dynamic valence states, facet effects, coordination environments and local reaction microenvironments. The divergent formation pathways of C 2 H 4 and C 2 H 5 OH are discussed in detail, focusing on intermediate evolution, competitive adsorption (*CO, *H, *OH) and electronic structure modulation. Key structure-activity relationships are revealed, offering insights into how oxidation state engineering can steer product selectivity. In parallel, degradation pathways such as Cu⁺ reduction, particle aggregation, and morphological collapse are analyzed, and advanced stability-by-design strategies including pulse electrolysis, heterostructure construction, doping, and surface coating are critically reviewed. Looking ahead, operando characterization, valence-interface precision engineering, and scalable catalyst architectures are expected to play critical roles in enabling the industrial implementation of CO 2 -to-C 2 conversion. By bridging mechanistic understanding with design strategies, this work provides a comprehensive framework for the rational development of efficient and durable CuO x catalysts.