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The influence of intrinsically proton conductive electrode binder materials on HT-PEMFC performance

Funda Arslan, Jens Dirsch, Maximilian Wagner, Anna T.S. Freiberg, Miriam Komma, Jochen Kerres, Simon Thiele, Thomas Böhm

2022Journal of Power Sources23 citationsDOIOpen Access PDF

Abstract

High temperature proton exchange membrane fuel cells (HT-PEMFCs) typically employ either acid-absorbing or hydrophobic electrode binders in their catalyst layers (CLs). A recently introduced alternative is the ionomeric binder PWN, poly(2,3,5,6-tetrafluorostyrene-4-phosphonic acid). In literature, PWN with a phosphonation degree of 70% was shown to remarkably improve HT-PEMFC performance. Here, we investigate the influence of the phosphonation degree (40–95%) of this ionomeric binder on HT-PEMFC performance. PWN is employed in the cathode CL and compared to the commonly used polytetrafluoroethylene (PTFE) binder. The electrochemical behavior is tested at 180 °C at ambient pressure under H2/air conditions using a commercial phosphoric acid (PA)-doped PBI-membrane. HT-PEMFCs with PWN generally outperform fuel cells (FCs) with PTFE after a full break-in regarding peak power density (PPD), activation overpotential (as studied by Tafel analysis), and reproducibility in the mass transport region. Further, PWN-electrodes show higher electrochemically active surface areas (ECSAs) than PTFE-electrodes after completing the break-in. We find that the phosphonation degree has a substantial impact on the PPD, with PWNs with lower phosphonation degrees (40–60%) outperforming highly phosphonated PWNs (70–95%). Taken together, PWN as an ionomeric electrode binder in HT-PEMFCs shows remarkable improvements in performance, but a precise adjustment of the phosphonation degree is required to obtain optimal results.

Topics & Concepts

Proton exchange membrane fuel cellMaterials scienceElectrodeCathodeElectrochemistryPhosphoric acidComposite materialChemical engineeringChemistryCatalysisOrganic chemistryPhysical chemistryMetallurgyEngineeringFuel Cells and Related MaterialsElectrocatalysts for Energy ConversionAdvanced battery technologies research