High Temperature Creep Behavior of Phosphoric Acid-Polybenzimidazole Gel Membranes

This work investigates the effects of polymer solids content and macromolecular structure on the high temperature creep behavior of polybenzimidazole (PBI) gel membranes imbibed with phosphoric acid (PA) after preparation via a polyphosphoric acid (PPA) mediated sol-gel process Low-solids, highly acid-doped PBI membranes demonstrate outstanding fuel cell performance under anhydrous, ambient pressure, and high temperature (120-200 degrees C) operating conditions. However, PBI membranes are susceptible to creep under compressive loads at elevated temperatures, so their long-term mechanical durability is a major concern. Here, we report results for the creep behavior of PBI membranes subject to compression at 180 degrees C. For para-and meta-PBI homopolymers, increasing polymer solids content results in lower creep compliance and higher extensional viscosity, which may be rationalized by increasing chain density in the sol-gel network. Comparing various homo-and copolymers at similar solids loading, differences in creep behavior may be rationalized in terms of chain-chain and chain-solvent interactions that control macromolecular solubility and stiffness in the PA solvent. The results demonstrate the feasibility of improving the mechanical properties of PA-doped PBI membranes by control of polymer solids content and rational design of PBI macromolecular structure. (C) 2015 Wiley Periodicals, Inc.