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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

2025Nature Communications6 citationsDOIOpen Access PDF

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.

Topics & Concepts

Formic acidElectrolysisAnodeMaterials scienceOxygen evolutionElectrochemistryElectric potential energyCatalysisProcess engineeringEnergy consumptionChemical engineeringFormateNanotechnologyElectrodeRenewable energyPower to gasElectric energy consumptionEnvironmental scienceElectrolytic cellChemistryHydrogen productionElectrocatalystCO2 Reduction Techniques and CatalystsCarbon dioxide utilization in catalysisIonic liquids properties and applications