Issue 8, 2016

Fine-grained and fully ordered intermetallic PtFe catalysts with largely enhanced catalytic activity and durability

Abstract

Catalytic activity and durability improvements are still the main challenges in fuel cell commercialization. To enhance nanocatalyst performance and durability for oxygen reduction reaction (ORR), we prepare 3.6 nm sized PtFe particles with a fully ordered intermetallic structure and entrap them in a porous carbon (PtFe@C). This nanocatalyst toward ORR exhibits 8–10 times enhancement in specific and mass activities over the commercial catalyst of Pt/C. Such a large enhancement is the highest, when compared with all other kinds of intermetallic catalysts reported in the literature. Accelerated durability testing has induced only a small change to the ordered structure and a minor loss of the activity after thousands of potential cycles under harsh electrochemical conditions. The high activity and durability are attributed to the fine-grained and ordered structure of the nanoparticle and the confining effect provided by the porous carbon. The nanoparticle, PtFe@C, represents a new strategy for performance optimization and cost reduction and promoting practical applications of fuel cells.

Graphical abstract: Fine-grained and fully ordered intermetallic PtFe catalysts with largely enhanced catalytic activity and durability

Supplementary files

Article information

Article type
Paper
Submitted
25 Apr 2016
Accepted
23 Jun 2016
First published
23 Jun 2016

Energy Environ. Sci., 2016,9, 2623-2632

Fine-grained and fully ordered intermetallic PtFe catalysts with largely enhanced catalytic activity and durability

X. X. Du, Y. He, X. X. Wang and J. N. Wang, Energy Environ. Sci., 2016, 9, 2623 DOI: 10.1039/C6EE01204C

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