Litcius/Paper detail

Gas–Liquid Decoupling Transport by Self-Draining in the Anode of Anion Exchange Membrane Fuel Cells

Guangyao Zhao, Zebi Chen, Xiaoyun Song, Qimei Yang, Jian Wang, Wei Ding, Zidong Wei

2025Journal of the American Chemical Society6 citationsDOI

Abstract

The gas–liquid decoupling transport represents a fundamental challenge in anode catalytic layers of anion exchange membrane fuel cells (AEMFCs), where water exhibits a paradoxical duality: as an essential transport medium for hydroxide ions (OH – ), yet as a kinetic-limiting product requiring immediate expulsion. Herein, we report a biomimetic capillary-driven water management strategy to achieve gas–liquid decoupling transport by engineering a hierarchically porous carbon nanofiber layer (CNL) as a self-draining anode catalytic layer (SD-ACL). The SD-ACL achieves anisotropic mass transport through structurally decoupled pathways: promoting rapid through-plane gas transport with a hydrophobic porous network while driving spontaneous in-plane water drainage via capillary action. As a result, the SD-ACL-fabricated membrane electrode assemble (MEA) achieved a high peak power density of 1150.3 mW cm –2 at high humidity with excellent durability, which was 2.3 times higher than that of the traditional one. Moreover, the SD-ACL could enhance nonprecious metal-anode-based AEMFCs by 57.5%, offering a promising strategy to achieve high-performance platinum-group metal-free (PGM-free) AEMFC technology.

Topics & Concepts

AnodeDecoupling (probability)ChemistryCatalysisMembraneChemical engineeringNanofiberWater transportElectrodeIon transporterHydroxidePorosityPower densityIonMembrane electrode assemblyIon exchangeAerogelInorganic chemistryMass transportCarbon nanofiberElectrochemistryCurrent densityPermeationCathodeCapillary actionNanotechnologyProton exchange membrane fuel cellSeparator (oil production)ConductivityLayer (electronics)NafionCarbon fibersElectrospinningPorous mediumFuel cellsFuel Cells and Related MaterialsElectrocatalysts for Energy ConversionMembrane-based Ion Separation Techniques