Fuel Cells

Title: Fuel Cells

Description:

AbstractThe sections in this article areIntroductionWorking Principles of Fuel CellsCell and Stack ConstructionAlkaline Fuel Cells (AFCs)Proton Exchange Membrane Fuel Cell (PEMFC)AHydrogen Proton Exchange Membrane Fuel CellBDirect Methanol Fuel Cell (DMFC)Phosphoric Acid Fuel Cell (PAFC)Molten Carbonate Fuel Cell (MCFC)Solid Oxide Fuel Cell (SOFC)Fuels for Fuel CellsThermodynamics and Kinetics of Fuel CellsLow‐Temperature Fuel Cells with Gaseous ReactantsElectro‐Oxidation of PureH2AFundamentalH2Oxidation and Evolution KineticsBVoltage Losses Due toH2Oxidation Kinetics in Low‐Temperature Fuel CellsAnodicH2Oxidation in the Presence ofCOContaminationAPractical Aspects of Fuel Cell Operation withCO‐ContaminatedH2BCOTolerance Mechanisms onPtAlloysCNew Research Directions for ImprovedCO‐Tolerant Anode CatalystsOxygen Reduction ReactionAOxygen Reduction Kinetics and Kinetic Losses inH2/Air Fuel CellsBQuantification of a Catalyst'sORRActivity inPEMFCsCORRActivity inPAFCsorH3PO4/PBI‐Based MembranesFCsDORRActivity inPEMFCsCompared with DiluteHClO4EPtParticle Size Effect on theORRActivityFORRMechanismGPtAlloys and OtherORRCatalystsCatalyst and Catalyst‐Induced Degradation MechanismsADissolution of Cathode Catalyst ConstituentsBCarbon Support CorrosionCImpact of ContaminantsDH2O2andOHRadical‐InducedPFSADegradationFuel Cells for Direct Oxidation of Liquid FuelsDirect Methanol Fuel CellsAState‐of‐the‐ArtDMFCPerformance LimitationsBAnode Catalyst Performance LimitationsCDMFCPerformance Limit with CurrentPtRuCatalystsDMethanol Electro‐Oxidation MechanismEPtRuCatalyst Modifications and Alternative CatalystsFMethanol‐Tolerant CathodesDirect Ethanol Fuel CellsDirect Formic Acid Fuel CellsFuel Cell ApplicationsGeneralTransportation ApplicationsStationary ApplicationPortable ApplicationsFinal CommentsAcknowledgments.