Issue 4, 2011

One-dimensional noble metal electrocatalysts: a promising structural paradigm for direct methanolfuelcells

Abstract

In this perspective, the catalytic shortfalls of contemporary DMFCs are discussed in the context of the materials that are currently being employed as electrocatalysts in both the anode and cathode. In light of these shortfalls, the inherent advantages of one-dimensional (1D) nanostructures are highlighted so as to demonstrate their potential as efficient, robust, and active replacements for contemporary nanoparticulate electrocatalysts. Finally, we review in detail the recent applications of 1D nanostructured electrocatalysts as both anodes and cathodes, and explore their potentially promising results towards improving DMFC efficiency and cost-effectiveness. In the case of cathode electrocatalysts, our group has recently prepared both 200 nm platinum nanotubes and ultrathin 2 nm platinum nanowires, which evinced two-fold and seven-fold enhancements in area specific ORR activity, respectively, as compared with contemporary commercial Pt nanoparticles. Similarly, the development of one-dimensional anodic electrocatalysts such as alloyed PtRu and PtCo nanowires, hierarchical Pt~Pd nanowires, and segmented PtRu systems have yielded promising enhancements towards methanol oxidation.

Graphical abstract: One-dimensional noble metal electrocatalysts: a promising structural paradigm for direct methanol fuel cells

Article information

Article type
Perspective
Submitted
28 Jun 2010
Accepted
20 Sep 2010
First published
18 Oct 2010

Energy Environ. Sci., 2011,4, 1161-1176

One-dimensional noble metal electrocatalysts: a promising structural paradigm for direct methanol fuel cells

C. Koenigsmann and S. S. Wong, Energy Environ. Sci., 2011, 4, 1161 DOI: 10.1039/C0EE00197J

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