Abstract
AbstractIn fuel‐cell catalyst layers (CLs), ionomers exists as nanoscale thin‐films binding catalyst particles, wherein ionic and gaseous species transport to catalyst sites. To improve film function, ionomers have been designed based on the prototypical perfluorosulfonic acid (PFSA). Since CLs are fabricated through solution‐based processing of inks, understanding how ink/dispersion solvent impacts ionomer interactions and function is important to guide future ionomer design. Herein, PFSA and its chemical derivatives are characterized from dispersion (in solvent) to thin film (cast on support) to investigate the impact of solvent water content on ionomer dispersion (structure, acidity) and resulting film properties. Dispersion characterization reveals that secondary aggregate structure depends on the sidechain chemistry, but all PFSA‐based ionomers evolve similarly as dispersion becomes water‐rich. The differences in aggregation alter ionomer adsorption and thin film morphology. Hydrophilic domain spacing and orientation are affected primarily by sidechain chemistry, and modulated by solvent composition. Thin‐film conductivity correlates with hydration and nanodomain alignment, signifying the role of morphology in properties. Overall, this work provides insights into how chemistry can be used to coarse‐tune structure–property relationships, while processing solvent is for fine‐tuning of dispersion‐film interplay for controlling CL‐ionomer function, which can be translated to other chemistries and ink formulations.
Published Version
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