Metalacarbon nanocomposites as the oxygen electrode for rechargeable lithium-air batteries

A key constituent in developing lithium-air batteries is the oxygen electrode, which facilitates the oxygen reduction reaction during the discharge process and the oxidation reaction of Li2O2 during the charge process. In this article, we report on the electrocatalytic activity of platinum, iridium,...

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Veröffentlicht in:	Electrochimica acta 2012-12, Vol.85, p.444-449
Hauptverfasser:	Ke, Fu-Sheng, Solomon, Bryan C, Ma, Shu-Guo, Zhou, Xiao-Dong
Format:	Artikel
Sprache:	eng
Schlagworte:	Alloy plating Chains Charge Crystallites Discharge Electric batteries Electrodes Lithium batteries Reduction
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creator	Ke, Fu-Sheng Solomon, Bryan C Ma, Shu-Guo Zhou, Xiao-Dong
description	A key constituent in developing lithium-air batteries is the oxygen electrode, which facilitates the oxygen reduction reaction during the discharge process and the oxidation reaction of Li2O2 during the charge process. In this article, we report on the electrocatalytic activity of platinum, iridium, and platinum-iridium alloy in an oxygen electrode. The average crystallite size of the previous metal nanoparticles was less than 2 nm, which were uniformly dispersed on the surface of chained Ketjenblack powder. Both chronoamperometry analysis and cell testing showed that Pt-Ir/C electrode exhibited superior activity and is the best electrode in this research. The discharge potentials for all three catalysts are similar, similar to 2.81 V vs. Li/Li+, and the discharge overpotential ( similar to 0.15 V) is very low. The charge overpotential for Pt-Ir/C composites was around 0.6 V.
doi_str_mv	10.1016/j.electacta.2012.08.023
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In this article, we report on the electrocatalytic activity of platinum, iridium, and platinum-iridium alloy in an oxygen electrode. The average crystallite size of the previous metal nanoparticles was less than 2 nm, which were uniformly dispersed on the surface of chained Ketjenblack powder. Both chronoamperometry analysis and cell testing showed that Pt-Ir/C electrode exhibited superior activity and is the best electrode in this research. The discharge potentials for all three catalysts are similar, similar to 2.81 V vs. Li/Li+, and the discharge overpotential ( similar to 0.15 V) is very low. 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subjects	Alloy plating Chains Charge Crystallites Discharge Electric batteries Electrodes Lithium batteries Reduction
title	Metalacarbon nanocomposites as the oxygen electrode for rechargeable lithium-air batteries
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