A pore-scale model of oxygen reduction in ionomer-free catalyst layers of PEFCs

Par Conseil national de recherches du Canada

DOI	Trouver le DOI : https://doi.org/10.1149/1.3505042
Auteur	Rechercher : Chan, K.; Rechercher : Eikerling, M.¹
Affiliation	Conseil national de recherches du Canada. Institut d'innovation en piles à combustible du CNRC
Format	Texte, Article
Sujet	Approximate analytical solutions; Catalyst layers; Cylindrical nanopores; Electrode potentials; Electrokinetic; Electrostatic interactions; Free channels; Helmholtz; Key determinants; Local current density; Materials selection; Metal phase; Metal surfaces; Nanostructural; Oxygen distribution; Oxygen Reduction; Platinum utilization; Poisson-Nernst-Planck theories; Polarization data; Polymer electrolyte fuel cells; Polymer electrolyte membranes; Pore wall; Pore-scale model; Potential distributions; Potential of zero charge; Proton migration; Stern model; Transport equation; Ultra-thin; Upscaling; Catalysts; Electrochemical electrodes; Electrolytic reduction; Fuel cells; Oxygen; Platinum; Poisson distribution; Polyelectrolytes; Pore pressure; Protons; Quay walls; Nanopores
Résumé	We present a model for oxygen reduction in water-filled, cylindrical nanopores with platinum walls. At one end, the pores are in contact with a polymer electrolyte membrane. The electrostatic interaction of the protons with the charged pore walls drives proton migration into the ionomer-free channels. We employ the Stern model to relate the surface charge density at the pore walls to the electrode potential. Proton and potential distributions within the pores are governed by the Poisson-Nernst-Planck theory and the oxygen distribution by Ficks law. Assuming a small local current density from oxygen reduction, we found an approximate analytical solution to the transport equations. The metal surface charge density and the corresponding proton conductivity of the pores are tuned by the deviation of the electrode potential from the potential of zero charge of the metal phase, which is the key determinant of the effectiveness of platinum utilization. Other determinants of pore performance are the Helmholtz capacitance, electrokinetic parameters, and pore size and length. Upon upscaling, the model is consistent with polarization data for ionomer-free, ultrathin catalyst layers in polymer electrolyte fuel cells (PEFCs). We discuss the implications of the model for the materials selection and nanostructural design of such catalyst layers. © 2010 The Electrochemical Society.
Date de publication	2011
Dans	Journal of the Electrochemical Society 158, nº 1 (2011) : B18–B28.
Langue	anglais
Publications évaluées par des pairs	Oui
Numéro NPARC	21271510
Exporter la notice	Exporter en format RIS
Signaler une correction	Signaler une correction (s'ouvre dans un nouvel onglet)
Identificateur de l’enregistrement	3d20a9b3-b832-4ace-a860-d416d97ee648
Enregistrement créé	2014-03-24
Enregistrement modifié	2020-04-21

Date de modification :: 2024-04-20