Alternative and facile production pathway towards obtaining high surface area PtCo/C intermetallic catalysts for improved PEM fuel cell performance

Philipp A Heizmann; Hien Nguyen; Miriam von Holst; Andreas Fischbach; Mitja Kostelec; Francisco Javier Gonzalez Lopez; Marjan Bele; Luka Pavko; Tina Đukić; Martin Šala; Francisco Ruiz-Zepeda; Carolin Klose; Matija Gatalo; Nejc Hodnik; Severin Vierrath; Matthias Breitwieser

doi:10.1039/d2ra07780a

Alternative and facile production pathway towards obtaining high surface area PtCo/C intermetallic catalysts for improved PEM fuel cell performance

RSC Adv. 2023 Feb 6;13(7):4601-4611. doi: 10.1039/d2ra07780a. eCollection 2023 Jan 31.

Authors

Philipp A Heizmann^{1

2}, Hien Nguyen^{1

3}, Miriam von Holst^{1

3}, Andreas Fischbach¹, Mitja Kostelec⁴, Francisco Javier Gonzalez Lopez^{4

5}, Marjan Bele⁴, Luka Pavko⁴, Tina Đukić⁴, Martin Šala⁶, Francisco Ruiz-Zepeda⁴, Carolin Klose^{1

3}, Matija Gatalo^{4

5}, Nejc Hodnik⁴, Severin Vierrath^{1

2

3}, Matthias Breitwieser^{1

3}

Affiliations

¹ Electrochemical Energy Systems, IMTEK - Department of Microsystems Engineering, University of Freiburg Georges-Koehler-Allee 103 79110 Freiburg Germany matthias.breitwieser@hahn-schickard.de.
² Institute and FIT - Freiburg Center for Interactive Materials and Bioinspired Technologies, University of Freiburg Georges-Köhler-Allee 105 79110 Freiburg Germany.
³ Hahn-Schickard Georges-Koehler-Allee 103 79110 Freiburg Germany.
⁴ Department of Materials Chemistry, National Institute of Chemistry Hajdrihova ulica 19 1000 Ljubljana Slovenia.
⁵ ReCatalyst d.o.o. Hajdrihova ulica 19 Ljubljana 1000 Slovenia.
⁶ Department of Analytical Chemistry, National Institute of Chemistry Hajdrihova ulica 19 1000 Ljubljana Slovenia.

Abstract

The design of catalysts with stable and finely dispersed platinum or platinum alloy nanoparticles on the carbon support is key in controlling the performance of proton exchange membrane (PEM) fuel cells. In the present work, an intermetallic PtCo/C catalyst is synthesized via double-passivation galvanic displacement. TEM and XRD confirm a significantly narrowed particle size distribution for the catalyst particles compared to commercial benchmark catalysts (Umicore PtCo/C). Only about 10% of the mass fraction of PtCo particles show a diameter larger than 8 nm, whereas this is up to or even more than 35% for the reference systems. This directly results in a considerable increase in electrochemically active surface area (96 m² g^-1 vs. >70 m² g^-1), which confirms the more efficient usage of precious catalyst metal in the novel catalyst. Single-cell tests validate this finding by improved PEM fuel cell performance. Reducing the cathode catalyst loading from 0.4 mg cm^-2 to 0.25 mg cm^-2 resulted in a power density drop at an application-relevant 0.7 V of only 4% for the novel catalyst, compared to the 10% and 20% for the commercial benchmarks reference catalysts.