%0 Journal Article %A Sarah A Berlinger %A Anamika Chowdhury %A Tim Van Cleve %A Aaron He %A Nicholas Dagan %A Kenneth C Neyerlin %A Bryan D McCloskey %A Clayton J Radke %A Adam Z Weber %B ACS Applied Materials & Interfaces %D 2022 %G eng %N 32 %P 36731 - 36740 %R 10.1021/acsami.2c10499 %T Impact of Platinum Primary Particle Loading on Fuel Cell Performance: Insights from Catalyst/Ionomer Ink Interactions %U https://pubs.acs.org/doi/10.1021/acsami.2c10499 %V 14 %8 08/2022 %! ACS Appl. Mater. Interfaces %X
A variety of electrochemical energy conversion technologies, including fuel cells, rely on solution-processing techniques (via inks) to form their catalyst layers (CLs). The CLs are heterogeneous structures, often with uneven ion-conducting polymer (ionomer) coverage and underutilized catalysts. Various platinum-supported-on-carbon colloidal catalyst particles are used, but little is known about how or why changing the primary particle loading (PPL, or the weight fraction of platinum of the carbon–platinum catalyst particles) impacts performance. By investigating the CL gas-transport resistance and zeta (ζ)-potentials of the corresponding inks as a function of PPL, a direct correlation between the CL high current density performance and ink ζ-potential is observed. This correlation stems from likely changes in ionomer distributions and catalyst–particle agglomeration as a function of PPL, as revealed by pH, ζ-potential, and impedance measurements. These findings are critical to unraveling the ionomer distribution heterogeneity in ink-based CLs and enabling enhanced Pt utilization and improved device performance for fuel cells and related electrochemical devices.