posted on 2016-10-24, 00:00authored byAn-Tsung Kuo, Wataru Shinoda, Susumu Okazaki
Many
morphological models have been proposed to describe the water
swelling behavior and proton transport mechanism of perfluorosulfonic
acid (PFSA) polymer membranes through experimental and modeling studies.
However, the ongoing structural debate has not been completely resolved
yet. We here conducted a series of all-atom molecular dynamics simulations
of hydrated PFSA membranes to evaluate changes in the membrane morphology
at different water contents. We found a similar dependence of the
morphology on the water content between PFSA membranes with equivalent
weight (EW) of 844 and 1144 g/equiv. That is, the morphology of the
aqueous domain changes with increasing water content from a channel-network
structure to a tortuous layered structure, and once attaining the
tortuous layered structure, the water layer just thickened gradually
by further increasing water content. Furthermore, we found more heterogeneous
water domains in the higher-EW PFSA membrane, demonstrating the stronger
aggregation behavior of the aqueous domains in the high-EW membranes.
The variation of the PFSA membrane morphology observed here is useful
to understand the proton transport mechanism and design new materials
suitable for polymer electrolyte fuel cells in the near future.