Hanna Steininger scite author profile

The melting behaviour and transport properties of straight chain alkanes mono- and difunctionalized with phosphonic acid groups have been investigated as a function of their length. The increase of melting temperature and decrease of proton conductivity with increasing chain length is suggested to be the consequence of an increasing ordering of the alkane segments which constrains the free aggregation of the phosphonic acid groups. However, the proton mobility is reduced to a greater extent than the proton diffusion coefficient indicating an increasing cooperativity of proton transport with increasing length of the alkane segment. The results clearly indicate that the "spacer concept", which had been proven successful in the optimization of the proton conductivity of heterocycle based systems, fails in the case of phosphonic acid functionalized polymers. Instead, a very high concentration of phosphonic acid functional groups forming "bulky" hydrogen bonded aggregates is suggested to be essential for obtaining very high proton conductivity. Aggregation is also suggested to reduce condensation reactions generally observed in phosphonic acid containing systems. On the basis of this understanding, the proton conductivities of poly(vinyl phosphonic acid) and poly(meta-phenylene phosphonic acid) are discussed. Though both polymers exhibit a substantial concentration of phosphonic acid groups, aggregation seems to be constrained to such an extent that intrinsic proton conductivity is limited to values below sigma = 10(-3) S cm(-1) at T = 150 degrees C. The results suggest that different immobilization concepts have to be developed in order to minimize the conductivity reduction compared to the very high intrinsic proton conductivity of neat phosphonic acid under quasi dry conditions. In the presence of high water activities, however, (as usually present in PEM fuel cells) the very high ion exchange capacities (IEC) possible for phosphonic acid functionalized ionomers (IEC >10 meq g(-1)) may allow for high proton conductivities in the intermediate temperature range (T approximately 120 -160 degrees C).

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

Kaltbeitzel

Schauff

Steininger³

et al. 2007

Solid State Ionics

117

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Intermediate temperature proton conductors based on phosphonic acid functionalized oligosiloxanes

et al. 2006

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Proton conductivity and diffusion study of molten phosphonic acid H3PO3

et al. 2008

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Poly(1,3‐phenylene‐5‐phosphonic Acid), a Fully Aromatic Polyelectrolyte with High Ion Exchange Capacity

et al. 2007

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Poly(1,3‐phenylene‐5‐phosphonic acid) is characterized by a high density of functional groups (less than 100 g/mol equivalent weight per proton), good thermo‐oxidative stability up to at least 200 °C, the absence of a softening point, and a proton conductivity of more than 2 × 10–3 S/cm between 110 °C and 160 °C under water vapor. Based on these properties, this polymer appears to be well suited as proton conducting component in polymer electrolyte membranes.

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