Litcius/Paper detail

Improving the Efficiencies of Water Splitting and CO<sub>2</sub> Electrolysis by Anodic O<sub>2</sub> Bubble Management

Shusheng Wan, Huanlei Zhang, Ke Ye, Jieyang Li, Yucheng He, Xiaolin Ge, Tongwen Xu, Wen‐Bin Cai, Meng Lin, Kun Jiang

2023The Journal of Physical Chemistry Letters17 citationsDOI

Abstract

This study systematically explores the impact of the anodic flow field design on the transport of O 2 bubble and subsequent energy efficiency in electrolysis devices. Two distinct configurations, namely a conventional serpentine flow panel and an interdigitated flow panel, are integrated at the anode side of the electrolyzer. The interdigitated flow field exhibits superior performance in both alkaline water splitting and CO 2 reduction despite the experience of an increased pressure drop. Numerical simulations reveal that the enhanced convective flow of the O 2 bubbles induced by a forced anolyte flow through the porous electrode within the interdigitated panel design resulted in a 3 orders of magnitude increase in the level of the O 2 bubble transport compared to the serpentine configuration. These findings not only underscore the significance of flow field design on bubble management but also provide a basis for advancing the electrolysis efficiency at industrial-level current densities.

Topics & Concepts

BubbleElectrolysisAnodeMaterials scienceElectrolysis of waterFlow (mathematics)Pressure dropAlkaline water electrolysisMechanicsDrop (telecommunication)ElectrodeMechanical engineeringChemistryEngineeringElectrolytePhysicsPhysical chemistryElectrocatalysts for Energy ConversionAdvanced battery technologies researchCO2 Reduction Techniques and Catalysts