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Experimental assessment of reverse water gas shift integrated with chemical looping for low-carbon fuels

Experimental assessment of reverse water gas shift integrated with chemical looping for low-carbon fuels
Experimental assessment of reverse water gas shift integrated with chemical looping for low-carbon fuels
Chemical looping integrated with reverse water gas (CL-RWGS) shift is presented in this study using Cu-based oxygen carrier (OC) supported on Al2O3 has been used to convert the CO2 and H2 mixture stream into a syngas stream with a tailored H2 to CO ratio and relevant conditions. The results demonstrated consistent breakthrough curves during redox cycles, confirming the chemical stability of the material. In 10 consecutive cycles at 600 °C and 1 bar, bed temperatures increased by 184 °C and 132 °C across the bed during oxidation and reduction stages respectively. The cooling effects during RWGS showed a decline in solid temperatures demonstrating the effectiveness of the heat removal strategy while attaining a CO2-to-CO conversion close >48%. The outlet gas maintains a H2/CO ratio above 2, confirming the material's dual role as OC and catalyst. During complete CL-RWGS cycles, varying temperature from 500 °C to 600 °C at a constant H2/CO2 molar ratio (1.3) and pressure (1 bar) reduces the H2/CO molar ratio from 3.14 to 2.35, respectively with a remarkable continuous CO2-to-CO conversion > 40%. The decrease in H2/CO molar ratio with the increase in temperature is consistent with the expected results of equilibrium limited conditions. Additionally, in CL-RWGS cycles, pressure insignificantly affects product molar composition. The study showed the capability of Cu material in converting CO2 into syngas through the CL-RWGS technique.
CCU, Chemical looping, Net zero emissions, Reverse water gas shift, Syngas production
2212-9839
Abbas, Syed Zaheer
3b02900e-fef6-40e1-acf7-96f26bfde4a8
de Leeuwe, Christopher
ccabf21e-0961-4a46-9774-76903f998a45
Amieiro, Alvaro
7f7937f5-f0c1-4a8a-9274-072d92d28c25
Poulston, Stephen
735e5938-fada-4ae9-8cfa-18dcad6113b9
Spallina, Vincenzo
800a70dc-9a6a-4aea-80af-9e0a51d72c52
Abbas, Syed Zaheer
3b02900e-fef6-40e1-acf7-96f26bfde4a8
de Leeuwe, Christopher
ccabf21e-0961-4a46-9774-76903f998a45
Amieiro, Alvaro
7f7937f5-f0c1-4a8a-9274-072d92d28c25
Poulston, Stephen
735e5938-fada-4ae9-8cfa-18dcad6113b9
Spallina, Vincenzo
800a70dc-9a6a-4aea-80af-9e0a51d72c52

Abbas, Syed Zaheer, de Leeuwe, Christopher, Amieiro, Alvaro, Poulston, Stephen and Spallina, Vincenzo (2024) Experimental assessment of reverse water gas shift integrated with chemical looping for low-carbon fuels. Journal of CO2 Utilization, 83, [102775]. (doi:10.1016/j.jcou.2024.102775).

Record type: Article

Abstract

Chemical looping integrated with reverse water gas (CL-RWGS) shift is presented in this study using Cu-based oxygen carrier (OC) supported on Al2O3 has been used to convert the CO2 and H2 mixture stream into a syngas stream with a tailored H2 to CO ratio and relevant conditions. The results demonstrated consistent breakthrough curves during redox cycles, confirming the chemical stability of the material. In 10 consecutive cycles at 600 °C and 1 bar, bed temperatures increased by 184 °C and 132 °C across the bed during oxidation and reduction stages respectively. The cooling effects during RWGS showed a decline in solid temperatures demonstrating the effectiveness of the heat removal strategy while attaining a CO2-to-CO conversion close >48%. The outlet gas maintains a H2/CO ratio above 2, confirming the material's dual role as OC and catalyst. During complete CL-RWGS cycles, varying temperature from 500 °C to 600 °C at a constant H2/CO2 molar ratio (1.3) and pressure (1 bar) reduces the H2/CO molar ratio from 3.14 to 2.35, respectively with a remarkable continuous CO2-to-CO conversion > 40%. The decrease in H2/CO molar ratio with the increase in temperature is consistent with the expected results of equilibrium limited conditions. Additionally, in CL-RWGS cycles, pressure insignificantly affects product molar composition. The study showed the capability of Cu material in converting CO2 into syngas through the CL-RWGS technique.

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Accepted/In Press date: 19 April 2024
e-pub ahead of print date: 24 April 2024
Published date: 24 April 2024
Keywords: CCU, Chemical looping, Net zero emissions, Reverse water gas shift, Syngas production

Identifiers

Local EPrints ID: 491090
URI: http://eprints.soton.ac.uk/id/eprint/491090
DOI: doi:10.1016/j.jcou.2024.102775
ISSN: 2212-9839
PURE UUID: 3da354f3-2227-4f1e-82eb-4f3cf34699f4
ORCID for Syed Zaheer Abbas: ORCID iD orcid.org/0000-0002-8783-8572

Catalogue record

Date deposited: 11 Jun 2024 23:55
Last modified: 12 Jun 2024 02:07

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Contributors

Author: Syed Zaheer Abbas ORCID iD
Author: Christopher de Leeuwe
Author: Alvaro Amieiro
Author: Stephen Poulston
Author: Vincenzo Spallina

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