Water sorption of poly(vinylphosphonic acid) and its influence on proton conductivity

Proton conductors based on phosphoric or phosphonic acid are considered very promising, due to their high charge carrier concentration, thermal stability and oxidation resistivity of the protogenic group. present work we have investigated well-characterized poly(vinylphosphonic acid) (PVPA). The material is hygroscopic, and we have studied the water content, self-condensation and proton conductivity as a function of relative humidity of air (RH). ondensation was determined by 31P NMR. Our data indicate that the RH determines both: the equilibrium ratio between condensed and non-condensed phosphonic OH-groups and the water content. At low RH, condensation and water coexist in the sample. RH exceeding 40% is needed to avoid self-condensation. This corresponds to a water sorption of ∼ 15 wt–% i.e.∼ 0.8 water molecules per phosphonic acid group; at higher humidity PVPA swells. Above 100 °C, self-condensation increases as water evaporates from the sample. This leads to condensation ratios of approximately 40% after 5 h under nitrogen atmosphere at 150 °C. Even under water vapor atmosphere, condensation ratios exceeding 30% were found at 150 °C. We proved that self-condensation is a reversible process up to temperatures as high as 250 °C. The proton conductivity was measured as a function of humidity and temperature under dry, humid and water vapor atmosphere.