Molecular Dynamics Simulations of Proton Transfer in a Model Nafion Pore

Author: Spohr, E.

Source: Molecular Simulation, Volume 30, Numbers 2-3, February, 2004 , pp. 107-115(9)

Publisher: Taylor and Francis Ltd

Key:

- Free Content

- New Content

- Subscribed Content

- Free Trial Content

Abstract:

Proton conducting polymer electrolyte membranes (PEM) for fuel cell applications often contain a sulfonated perfluorinated side chain, which is attached to a polymeric backbone. Proton conductance in such membranes is a complicated process, which depends on both material properties and operational parameters of the fuel cell. Experimentally, it is well established that proton conductivity in such membranes is strongly dependent on water content, approaching that of bulk water at high water content. The goal of the present study is to analyze the relationship between pore structure on the molecular level and proton transfer dynamics as a function of water content and side chain density. A molecular model of the side chain has been developed and is used to simulate proton transport in a simple slab pore. The polymer backbone is represented as a simple excluded volume, described by a Lennard-Jones interaction potential.

Keywords: Proton transfer; Model Nafion Pore; Polymer electrolyte membrane; Direct methanol fuel cell

Document Type: Research article

DOI: 10.1080/0892702301000152208

The full text electronic article is available for purchase. You will be able to download the full text electronic article after payment.

$45.29 plus tax Refund Policy