Theoretical Study on Reactivity of Cu-Based Oxygen Carrier for CO Chemical Looping Combustion

Lei Wang; Wu Qin; Ling Nan Wu; Xue Qing Hu; Ming Zhong Gao; Jun Jiao Zhang; Chang Qing Dong; Yong Ping Yang

doi:10.4028/www.scientific.net/AMR.805-806.1336

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 805-806Theoretical Study on Reactivity of Cu-Based Oxygen...

Theoretical Study on Reactivity of Cu-Based Oxygen Carrier for CO Chemical Looping Combustion

Abstract:

The reaction of Cu-based oxygen carrier with CO during chemical looping combustion was studies using density functional theory (DFT) calculations in this paper. It was found that CO₂ is formed after CO chemically adsorbed onto CuO surface and it exhibits strong localization properties. Energy barrier with regard to the overall reaction is 1.947 eV with overall reaction energy of-3.686 eV, indicating the overall reaction is an exothermic process. As can be figured out from the geometries of the stable structures, after the physical adsorption of CO on CuO surface, 1.947 eV is needed to jump to the transition state, and the nearest distance between CO and the surface is 1.542 Å with bond angle of 155.381°, C-O bond has stretched to 1.151 Å from 1.147 Å. With further interaction between CO and CuO surface, nearly linear structure O-C-O group is formed with bond angle of 179.177° and almost symmetric C-O bond distance, which was thought to be the formation of CO₂.

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Periodical:

Advanced Materials Research (Volumes 805-806)

Pages:

1336-1339

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.805-806.1336

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Online since:

September 2013

Authors:

Lei Wang*, Wu Qin, Ling Nan Wu, Xue Qing Hu, Ming Zhong Gao, Jun Jiao Zhang, Chang Qing Dong, Yong Ping Yang

Keywords:

Chemical-Looping Combustion, Co, CuO, DFT

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