, New Ion-exchange Membranes Derived from Polyketone

Anion-exchange membrane fuel cells (AEMFCs) provide significant advantages over their proton-exchange membrane counterparts. In the alkaline environment, the oxygen reduction reaction (ORR) is more facile, there is diminished fuel crossover, and a greater flexibility regarding fuel and catalyst choice. The membrane at the heart of AEMFCs not only facilitates the ion exchange but also separates the fuel feedstocks and acts as a support for the membrane-electrode assembly (MEA). However, to date there are still no membrane materials that satisfy all the needs (long-term stability in alkaline environment, high ionic conductivity, low swelling and good structural integrity) for use in AEMFCs and this remains one of the larger obstacles for further AEMFC development. The amination and subsequent quarternisation of polyketone leads to a new family of ionomers containing N-substituted pyrrole moieties. The degree of amination can be controlled by manipulating reaction conditions, allowing the composition and resulting structural properties of the polymer to be tuned [1,2]. Membrane fabrication results in thermally stable (TD > 250 °C), structurally robust polymer electrolytes that exhibit ionic conductivity (> 10-3 S cm-1). These new solid-state ion-conducting materials have the potential to be used in a variety of applications including AEMFCs. Here we present an in-depth study focusing on the structure-property relationships of this new polypyrrole/polyketone polymer. A variety of analytical techniques are used to probe the thermal and structural properties of the polymers, these include highresolution thermogravimetric analysis, modulated differential scanning calorimetry, dynamic mechanical analysis, vibrational, NMR and UV-Vis spectroscopies. In addition, broadband electrical spectroscopy is used to gauge the interplay between the structural properties and electrical response [3]. Acknowledgements: The authors wish to thank the Strategic Project of the University of Padova “Materials for Membrane-Electrode Assemblies to Electric Energy Conversion and Storage Devices (MAESTRA)” for funding. [1] A. Sen, Z. Jiang, and J. T. Chen, Macromolecules 22 (1989) 2012-2014. [2] N. Ataollahi, K. Vezzù, G. Nawn, G. Pace, G. Cavinato, F. Girardi, P. Scardi, V. Di Noto, and R. Di Maggio, Electrochim. Acta 226 (2017) 148-157. [3] V. Di Noto, G. A. Guinevere, K. Vezzù, G. Nawn, F. Bertasi, T. H. Tsai, A. Maes, S. Seifert, B. Coughlin, and A. Herring, Phys. Chem. Chem. Phys. 17 (2015) 31125-31139.