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Composite Anode for PEM Water Electrolyzers: Lowering Iridium Loadings and Reducing Material Costs with a Conductive Additive

Kara J. Ferner, Shawn Litster

2024ACS Applied Energy Materials53 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide To enable the greater installed capacity of proton exchange membrane water electrolysis (PEMWE) for clean hydrogen production, associated costs must be lowered while achieving high current density performance and durability. Scarce and expensive iridium (Ir) required for the oxygen evolution reaction (OER) is a large contributor to the overall cost, yet high loadings of Ir (1–2 mg Ir cm –2 ) are currently needed in commercial systems to maintain sufficient activity, conductivity, and durability. To meet the aggressive targets for low Ir loadings, we introduce a composite anode approach using a conductive additive that is less expensive than Ir to facilitate robust, high-performance operation with low Ir loading by retaining electrode thickness and in-plane electrical conductivity. In this demonstration, we use platinum (Pt) black as the conductive additive given its high electrical conductivity, acid stability, and current price one-fifth that of Ir. Using a high-activity commercial Ir oxide (IrO x ) catalyst, we present a 95% Ir loading reduction and 80% cost reduction of the anode catalyst materials while maintaining equal current density performance at a cell voltage of 1.8 V. Furthermore, we show enhanced stability of a composite anode compared to an IrO x anode with loadings of 0.10 mg Ir cm –2 via accelerated stress test (AST) and postmortem imaging. With this approach, we show promising results toward lowering Ir loadings and material costs, addressing a significant barrier to the widespread adoption of PEMWE for clean hydrogen production.

Topics & Concepts

IridiumAnodeProton exchange membrane fuel cellElectrolysisElectrolysis of waterDurabilityPolymer electrolyte membrane electrolysisHydrogen productionComposite numberOxygen evolutionMaterials scienceHydrogenElectrochemistryWaste managementEnvironmental scienceChemical engineeringChemistryComposite materialCatalysisElectrodeFuel cellsEngineeringBiochemistryOrganic chemistryElectrolytePhysical chemistryHybrid Renewable Energy SystemsHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen Reduction
Composite Anode for PEM Water Electrolyzers: Lowering Iridium Loadings and Reducing Material Costs with a Conductive Additive | Litcius