“…The electrochemical reduction of CO 2 (CO 2 RR) represents a pivotal advancement toward achieving sustainable carbon neutrality, − facilitating the transformation of greenhouse gases into valuable fuels and chemical precursors. − Among the array of products, multicarbon (C 2 ) products stand out due to their high energy densities and significant economic value, marking them as prime targets for industrial utilization. − Currently, copper-based (Cu) catalysts are distinguished for their unique ability to promote C–C coupling, making them the sole class of materials proficient in selectively converting CO 2 to valuable C 2 products such as ethylene and ethanol. ,,− However, these materials often undergo uncontrollable structural changes during CO 2 RR, jeopardizing the integrity of active sites and leading to diminished catalytic efficiency or complete activity loss. , Interestingly, the CuO x catalysts have demonstrated robust performance, benefiting from certain restructuring effects. ,, Notably, the coexistence of Cu + and Cu 0 states has been identified as crucial for enhancing the selectivity to C 2 products. ,− However, the thermodynamic instability of Cu + predisposes it to reduction to Cu 0 under operational conditions, posing significant stability challenges. To address these challenges, approaches including the deployment of organic ligands, the integration of auxiliary metals, and the utilization of Cu-based catalyst have been explored. ,,− However, these methods frequently encounter limitations in catalytic performance, stability, and capacity to scale up.…”