| Literature DB >> 32839587 |
Gustav W Sievers1,2, Anders W Jensen3, Jonathan Quinson3, Alessandro Zana3,4, Francesco Bizzotto4, Mehtap Oezaslan5,6, Alexandra Dworzak5,6, Jacob J K Kirkensgaard7,8, Thomas E L Smitshuysen9, Shima Kadkhodazadeh9, Mikkel Juelsholt3, Kirsten M Ø Jensen3, Kirsten Anklam10, Hao Wan3, Jan Schäfer10, Klára Čépe11, María Escudero-Escribano3, Jan Rossmeisl3, Antje Quade10, Volker Brüser10, Matthias Arenz12,13.
Abstract
Several concepts for platinum-based catalysts for the oxygen reduction reaction (ORR) are presented that exceed the US Department of Energy targets for Pt-related ORR mass activity. Most concepts achieve their high ORR activity by increasing the Pt specific activity at the expense of a lower electrochemically active surface area (ECSA). In the potential region controlled by kinetics, such a lower ECSA is counterbalanced by the high specific activity. At higher overpotentials, however, which are often applied in real systems, a low ECSA leads to limitations in the reaction rate not by kinetics, but by mass transport. Here we report on self-supported platinum-cobalt oxide networks that combine a high specific activity with a high ECSA. The high ECSA is achieved by a platinum-cobalt oxide bone nanostructure that exhibits unprecedentedly high mass activity for self-supported ORR catalysts. This concept promises a stable fuel-cell operation at high temperature, high current density and low humidification.Entities:
Year: 2020 PMID: 32839587 DOI: 10.1038/s41563-020-0775-8
Source DB: PubMed Journal: Nat Mater ISSN: 1476-1122 Impact factor: 43.841