Membrane-free CO2 electrolyzer design for economically efficient formic acid electro-synthesis
Xiaotong Li, Kainan Gao, Mingbo Qu, Nanhui Li, Xiangzhou Lv, Xiuju Wu, Qingyang Lin, Hao Bin Wu
Abstract
Reducing the electrical energy consumption for formic acid electro-synthesis is indispensable for advancing its industrial implementation. In a conventional CO2 electrolyzer, most input electrical energy is consumed by the unprofitable anodic oxygen evolution reaction (OER) and ohmic drop. Electrolyzer engineering provides a promising platform to boost electrical energy utilization efficiency beyond catalyst optimization. Herein, we demonstrate a membrane-free CO2 electrolyzer design that pairs electrochemical CO2 reduction (CO2R) with an all-liquid-phase anodic reaction, enabling dual production of formate at both electrodes with significantly reduced cell voltage. The optimized design exhibits the lowest electrical energy consumption (< 310 kJ mol-1formate) at cell voltages below 2.7 V across a current density range of 0.05–0.4 A cm-2. This cell also maintains stable operation at 2.25 V for 313 h with a < 20 % increase in electrical energy consumption. Systematic techno-economic analysis (TEA) evaluates the economic viability of this design for formic acid electro-synthesis, revealing a potential roadmap towards low-cost formic acid production. This strategy provides guidelines for CO2R electrolyzer engineering toward energy-efficient, economically viable production of valuable chemicals. Electrolyzer engineering provides a promising platform to boost energy utilization beyond catalyst optimization. Here, the authors report a membrane-free CO2 electrolyzer that enables energy-efficient and economically viable electrosynthesis of formic acid.