(35f) Surface Dealloyed Pt Nanoparticles Supported On Carbon Nanotubes: Facile Synthesis and Promising Applications for Direct Crude Glycerol Anion-Exchange Membrane Fuel Cell
AIChE Annual Meeting
2013
2013 AIChE Annual Meeting
Energy and Transport Processes
Advances in Fuel Cell and Battery Technologies I
Monday, November 4, 2013 - 10:20am to 10:42am
Surface
dealloyed PtCo nanoparticles supported on carbon nanotube: facile synthesis and
promising application for anion exchange membrane direct crude glycerol fuel
cell
Ji Qi1,
Le Xin1, David Chadderdon1, Yang Qiu1, Yibo
Jiang2, Kai Sun3, Haiying He4, Zhiyong Zhang1,
Changhai Liang5, Wenzhen Li1
1Department of Chemical Engineering,
Michigan Technological University
2Department of Civil & Environmental
Engineering, Michigan Technological University
3Department of Materials Science and
Engineering, University of Michigan
4Department of Physics, Michigan
Technological University
5School of Chemical Engineering, Dalian
University of Technology
6Department of Materials Science and Engineering,
Michigan Technological University
Due to the fast growth of global energy needs and
quickly diminishing of fossil fuel resources, people are forced to seek
reliable, high performance, cost-effective and environmentally-beneficial
renewable energy sources. Anion exchange membrane based direct alcohol fuel
cells have recently attract enormous attention as a potential solution to
alleviate the current energy issues.
Exploring crude glycerol as fuel for direct alcohol fuel cells not only provides a promising solution to
using excessive biodiesel byproduct, but also opens a new avenue towards
development of low-cost alcohol fuel cells. In the present study, surface dealloyed PtCo
nanoparticles supported on carbon nanotube (SD-PtCo/CNT) were prepared by ex
situ method and used for crude glycerol oxidation for the first time.
SD-PtCo/CNT anode catalyst based AEMFC with a 0.5 mgPt cm-2
achieved peak power densities of 268.5 mW cm-2 (crude glycerol/O2)
and 284.6 mW cm-2 (high purity glycerol/O2)at
80 oC and ambient pressure, which are close to the published result
of direct high purity glycerol solid oxide fuel cell operated at high
temperature of 800 oC (327 mW cm-2), and are higher than
all other published performances of direct high purity glycerol microbial fuel
cell and anion exchange membrane fuel cell. This work successfully developed a
high output power direct alcohol fuel cells with biorenewable,
environmentally-friendly fuel and dealloy technique prepared catalyst, which
will substantially impact
future catalyst design and fuel cell development.
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