Semiempirical model based on thermodynamic principles for determining 6 kW proton exchange membrane electrolyzer stack characteristics

Journal of Power Sources

Volumn 185, Issue 2, 2008, Pages 1348-1353

  Dale, N V ^a   Mann, M D ^a   Salehfar, H ^b  

^a University of North Dakota   (United States)

^b UNIVERSITY OF NORTH DAKOTA   (United States)

Author keywords

Exchange current density; Membrane conductivity; PEM electrolysis; Reversible potential

Indexed keywords

CELL MEMBRANES; CURVE FITTING; ELECTRIC CONDUCTIVITY; ELECTROLYTIC CELLS; ENERGY EFFICIENCY; ION EXCHANGE MEMBRANES; IONIC CONDUCTIVITY; MEMBRANES; NONLINEAR EQUATIONS; NUMERICAL ANALYSIS; PRESSURE EFFECTS; PROTONS; TEMPERATURE; THERMODYNAMICS;

ACTIVATION OVERPOTENTIAL; CELL VOLTAGES; ELECTROLYZER; EQUATION COEFFICIENTS; EXCHANGE CURRENT DENSITIES; EXCHANGE CURRENT DENSITY; EXPERIMENTAL SYSTEMS; HIGHER HEATING VALUES; MEMBRANE CONDUCTIVITIES; MEMBRANE CONDUCTIVITY; MODEL COMPONENTS; MODELING RESULTS; NERNST POTENTIALS; NONLINEAR CURVE FITTINGS; OHMIC OVERPOTENTIAL; PEM ELECTROLYSIS; PEM ELECTROLYZER; PRESSURE DEPENDENTS; PROTON EXCHANGE MEMBRANES; REVERSIBLE POTENTIAL; REVERSIBLE POTENTIALS; SEMIEMPIRICAL EQUATIONS; SEMIEMPIRICAL MODELS; STACK TEMPERATURES; TEMPERATURE DEPENDENCES; TEMPERATURE DEPENDENTS; VOLTAGE CHARACTERISTICS;

CURRENT VOLTAGE CHARACTERISTICS;

EID: 56049085808     PISSN: 03787753     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jpowsour.2008.08.054     Document Type: Article

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