Enhancing Cathode Performance and Anode Sulfur/Carbon Tolerance of SOFCs by Nano-Infiltration

The positive cost benefit associated with the use of metallic interconnects in SOFCs have led commercial developers to target operating temperatures in the range of 600{degree sign}C-800 {degree sign}C; however maintaining high electrode performance at reduced temperatures remains a challenge. One a...

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Hauptverfasser:	Sholklapper, Tal, Kurokawa, Hideto, Jacobson, Craig P., Visco, Steven J., De Jonghe, Lutgrad C.
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creator	Sholklapper, Tal Kurokawa, Hideto Jacobson, Craig P. Visco, Steven J. De Jonghe, Lutgrad C.
description	The positive cost benefit associated with the use of metallic interconnects in SOFCs have led commercial developers to target operating temperatures in the range of 600{degree sign}C-800 {degree sign}C; however maintaining high electrode performance at reduced temperatures remains a challenge. One approach to increase electrode performance is to enhance the active catalytic area by infiltrating the electrode with dispersed catalyst. LBNL has developed an infiltration method that deposits a continuous network of nano-particles throughout existing electrodes, in a single processing step. In the case of mixed ionic electronic conductor (MIEC) nanoparticles infiltrated into LSM-YSZ electrodes, electrode performance is greatly improved by both the catalytic properties of the MIEC and the triple-phase boundary extension across the surfaces of both the electrode and electrolyte particles in the electrode. The infiltration method has additionally been used to deposit MIEC nanoparticles in Ni-YSZ electrodes, leading not only to improved performance, but to impressive sulfur tolerance as well.
doi_str_mv	10.1149/1.2729173
format	Conference Proceeding
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One approach to increase electrode performance is to enhance the active catalytic area by infiltrating the electrode with dispersed catalyst. LBNL has developed an infiltration method that deposits a continuous network of nano-particles throughout existing electrodes, in a single processing step. In the case of mixed ionic electronic conductor (MIEC) nanoparticles infiltrated into LSM-YSZ electrodes, electrode performance is greatly improved by both the catalytic properties of the MIEC and the triple-phase boundary extension across the surfaces of both the electrode and electrolyte particles in the electrode. 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identifier	ISSN: 1938-5862
ispartof	ECS transactions, 2007, Vol.7 (1), p.837-843
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language	eng
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source	IOP Publishing Journals; Institute of Physics (IOP) Journals - HEAL-Link
title	Enhancing Cathode Performance and Anode Sulfur/Carbon Tolerance of SOFCs by Nano-Infiltration
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