Litcius/Paper detail

Modelling the Proton-Conductive Membrane in Practical Polymer Electrolyte Membrane Fuel Cell (PEMFC) Simulation: A Review

Edmund J. F. Dickinson, Graham T. Smith

2020Membranes91 citationsDOIOpen Access PDF

Abstract

Theoretical models used to describe the proton-conductive membrane in polymer electrolyte membrane fuel cells (PEMFCs) are reviewed, within the specific context of practical, physicochemical simulations of PEMFC device-scale performance and macroscopically observable behaviour. Reported models and their parameterisation (especially for Nafion 1100 materials) are compiled into a single source with consistent notation. Detailed attention is given to the Springer-Zawodzinski-Gottesfeld, Weber-Newman, and "binary friction model" methods of coupling proton transport with water uptake and diffusive water transport; alongside, data are compiled for the corresponding parameterisation of proton conductivity, water sorption isotherm, water diffusion coefficient, and electroosmotic drag coefficient. Subsequent sections address the formulation and parameterisation of models incorporating interfacial transport resistances, hydraulic transport of water, swelling and mechanical properties, transient and non-isothermal phenomena, and transport of dilute gases and other contaminants. Lastly, a section is dedicated to the formulation of models predicting the rate of membrane degradation and its influence on PEMFC behaviour.

Topics & Concepts

Proton exchange membrane fuel cellElectrolyteContext (archaeology)MembraneNafionDiffusionProton transportHydraulic conductivityMaterials scienceWater transportConductivityIsothermal processThermodynamicsMechanicsChemistryChemical engineeringEnvironmental sciencePhysicsEnvironmental engineeringEngineeringElectrochemistryPhysical chemistryWater flowElectrodeBiochemistrySoil scienceSoil waterPaleontologyBiologyFuel Cells and Related MaterialsElectrocatalysts for Energy ConversionAdvancements in Solid Oxide Fuel Cells