Abstract
Production of hydrocarbon-based, alkaline exchange, membrane–electrode assemblies (MEA’s) for fuel cells and electrolyzers is examined via catalyst-coated membrane (CCM) and gas-diffusion electrode (GDE) fabrication routes. The inability effectively to hot-press hydrocarbon-based ion-exchange polymers (ionomers) risks performance limitations due to poor interfacial contact, especially between GDE and membrane. The addition of an ionomeric interlayer is shown greatly to improve the intimacy of contact between GDE and membrane, as determined by ex situ through-plane MEA impedance measurements, indicated by a strong decrease in the frequency of the high-frequency zero phase angle of the complex impedance, and confirmed in situ with device performance tests. The best interfacial contact is achieved with CCM’s, with the contact impedance decreasing, and device performance increasing, in the order GDE >> GDE+Interlayer > CCM. The GDE+interlayer fabrication approach is further examined with respect to hydrogen crossover and alkaline membrane electrolyzer cell performance. An interlayer strongly reduces the rate of hydrogen crossover without strongly decreasing electrolyzer performance, while crosslinking the ionomeric layer further reduces the crossover rate though also limiting device performance. The approach can be applied and built upon to improve the design and production of alkaline, and more generally, hydrocarbon-based MEA’s and exchange membrane devices.
Highlights
Anion exchange membrane (AEM) devices have shown tremendous progress in the last few years [1]
This work highlights the importance of the method of fabrication of alkaline membrane device membrane–electrode assemblies (MEA’s), and is likely generalizable to most hydrocarbon-based exchange membrane devices
We showed that adding an ionomeric interlayer to gas diffusion electrodes, which otherwise show poor interfacial contact to the membrane in an membrane–electrode assembly (MEA), greatly mitigates this ‘intimacy-of-contact’ problem
Summary
Anion exchange membrane (AEM) devices have shown tremendous progress in the last few years [1]. Dioxide Materials have reported over 10,000 hours in an alkaline water electrolyzer using Sustainion® GradeT membrane, at 60 ◦C and 1 A/cm current density [5]. These standout results herald significant steps towards demonstrating the full commercial potential of AEM technology. They are the culmination of community-wide efforts over the last two decades to identify and resolve the many scientific and technological challenges faced by AEM devices, the essence of which has been covered in several recent reviews [3,4,6,7]
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