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Efficient Removal of Methane over Cobalt-Monoxide-Doped AuPd Nanocatalysts.

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Bibliographic Details
Title:	Efficient Removal of Methane over Cobalt-Monoxide-Doped AuPd Nanocatalysts.
Authors:	Shaohua Xie¹, Yuxi Liu¹ yxliu@bjut.edu.cn, Jiguang Deng¹ jgdeng@bjut.edu.cn, Simiao Zang¹, Zhenhua Zhang², Arandiyan, Hamidreza³, Hongxing Dai¹ hxdai@bjut.edu.cn
Source:	Environmental Science & Technology. 2/21/2017, Vol. 51 Issue 4, p2271-2279. 9p.
Subjects:	Alloys, Nanoparticles, Methane in water, Hydroxyl group, Water vapor
Abstract:	To overcome deactivation of Pd-based catalysts at high temperatures, we herein design a novel pathway by introducing a certain amount of CoO to the supported Au-Pd alloy nanoparticles (NPs) to generate high-performance Au-Pd-xCoO/three- dimensionally ordered macroporous (3DOM) Co3O4 (x is the Co/Pd molar ratio) catalysts. The doping of CoO induced the formation of PdO-CoO active sites, which was beneficial for the improvement in adsorption and activation of CH4 and catalytic performance. The Au-Pd- 0.40CoO/3DOM Co3O4 sample performed the best (T90% = 341 °C at a space velocity of 20--000 mL g-1 h-1). Deactivation of the 3DOM Co3O4-supported Au-Pd, Pd-CoO, and Au-Pd-xCoO nanocatalysts resulting from water vapor addition was due to the formation and accumulation of hydroxyl on the catalyst surface, whereas deactivation of the Pd-CoO/3DOM Co3O4 catalyst at high temperatures (680-800 °C) might be due to decomposition of the PdOy active phase into aggregated Pd0 NPs. The Au-Pd-xCoO/3DOM Co3O4 nanocatalysts exhibited better thermal stability and water tolerance ability compared to the 3DOM Co3O4-supported Au-Pd and Pd-CoO nanocatalysts. We believe that the supported Au-Pd-xCoO nanomaterials are promising catalysts in practical applications for organic combustion. [ABSTRACT FROM AUTHOR]
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Database:	Engineering Source

Description
Abstract:	To overcome deactivation of Pd-based catalysts at high temperatures, we herein design a novel pathway by introducing a certain amount of CoO to the supported Au-Pd alloy nanoparticles (NPs) to generate high-performance Au-Pd-xCoO/three- dimensionally ordered macroporous (3DOM) Co3O4 (x is the Co/Pd molar ratio) catalysts. The doping of CoO induced the formation of PdO-CoO active sites, which was beneficial for the improvement in adsorption and activation of CH4 and catalytic performance. The Au-Pd- 0.40CoO/3DOM Co3O4 sample performed the best (T90% = 341 °C at a space velocity of 20--000 mL g-1 h-1). Deactivation of the 3DOM Co3O4-supported Au-Pd, Pd-CoO, and Au-Pd-xCoO nanocatalysts resulting from water vapor addition was due to the formation and accumulation of hydroxyl on the catalyst surface, whereas deactivation of the Pd-CoO/3DOM Co3O4 catalyst at high temperatures (680-800 °C) might be due to decomposition of the PdOy active phase into aggregated Pd0 NPs. The Au-Pd-xCoO/3DOM Co3O4 nanocatalysts exhibited better thermal stability and water tolerance ability compared to the 3DOM Co3O4-supported Au-Pd and Pd-CoO nanocatalysts. We believe that the supported Au-Pd-xCoO nanomaterials are promising catalysts in practical applications for organic combustion. [ABSTRACT FROM AUTHOR]
ISSN:	0013936X
DOI:	10.1021/acs.est.6b03983