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Impact of Local Microenvironments on the Selectivity of Electrocatalytic Nitrate Reduction in a BPM‐MEA System

Po‐Wei Huang, Hakhyeon Song, Jae‐Young Yoo, Danae A. Chipoco Haro, Hyuck Mo Lee, Andrew J. Medford, Marta C. Hatzell

2024Advanced Energy Materials39 citationsDOIOpen Access PDF

Abstract

Abstract Electrochemical nitrate reduction reaction (NO 3 RR) has garnered increasing attention as a pathway for converting a harmful pollutant (nitrate) into a value‐added product (ammonia). However, high selectivity toward ammonia (NH 3 ) is imperative for process viability. Optimizing proton availability near the catalyst is important for achieving selective NH 3 production. Here, the aim is to systematically examine the impacts of proton availability on NO 3 RR selectivity in a bipolar membrane (BPM)‐based membrane electrode assembly (MEA) system. The BPM generates a proton flux from the membrane toward the catalyst during electrolysis. Thus, the BPM‐MEA system can modulate the proton flux during operation. The impact of interposer layers, proton scavenging electrolytes (CO 3 2− ), and catalyst configurations are also examined to identify which local microenvironments favor ammonia formation. It is found that a moderate proton supply allows for an increase in ammonia yield by 576% when compared to the standard MEA setup. This also results in a high selectivity of 26 (NH 3 over NO 2 − ) at an applied current density of 200 mA cm −2 .

Topics & Concepts

AmmoniaNitrateSelectivityCatalysisMaterials scienceElectrolyteAmmonia productionElectrolysisElectrochemistryProton exchange membrane fuel cellMembraneInorganic chemistryMembrane electrode assemblyChemical engineeringProtonElectrodeChemistryOrganic chemistryPhysical chemistryBiochemistryEngineeringPhysicsQuantum mechanicsAmmonia Synthesis and Nitrogen ReductionCaching and Content DeliveryAdvanced Photocatalysis Techniques
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