One-step plasma-enabled catalytic carbon dioxide hydrogenation to higher hydrocarbons: significance of catalyst-bed configuration

Jiajie Wang; Mohammad S. AlQahtani; Xiaoxing Wang; Sean D. Knecht; Sven G. Bilén; Chunshan Song; Wei Chu

doi:10.1039/d0gc03779f

One-step plasma-enabled catalytic carbon dioxide hydrogenation to higher hydrocarbons: significance of catalyst-bed configuration

Jiajie Wang, Mohammad S. AlQahtani, Xiaoxing Wang, Sean D. Knecht, Sven G. Bilén, Chunshan Song, Wei Chu

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Effectively converting CO₂into fuels and value-added chemicals remains a major challenge in catalysis, especially under mild conditions. In this study, we report a one-step plasma-enabled catalytic process for CO₂hydrogenation to C₂⁺hydrocarbons operated at low temperature and atmospheric pressure in a dielectric barrier discharge (DBD) packed-bed reactor. Plasma without catalyst produces mainly CO (over 80% selectivity), while CH₄becomes the main product when plasma is coupled with the alumina-supported Co catalyst. Interestingly, by simply changing the catalyst-bed configuration within the plasma discharge zone, more C₂⁺hydrocarbons are selectively produced. High C₂⁺hydrocarbons selectivity of 46% atca.74% CO₂conversion is achieved when operated at the furnace temperature of 25 °C and 10 W DBD plasma. The possible origin of C₂⁺formation and the significance of catalyst-bed configuration are discussed.

Original language	English (US)
Pages (from-to)	1642-1647
Number of pages	6
Journal	Green Chemistry
Volume	23
Issue number	4
DOIs	https://doi.org/10.1039/d0gc03779f
State	Published - Feb 21 2021

All Science Journal Classification (ASJC) codes

Environmental Chemistry
Pollution

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10.1039/d0gc03779f

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title = "One-step plasma-enabled catalytic carbon dioxide hydrogenation to higher hydrocarbons: significance of catalyst-bed configuration",

abstract = "Effectively converting CO2into fuels and value-added chemicals remains a major challenge in catalysis, especially under mild conditions. In this study, we report a one-step plasma-enabled catalytic process for CO2hydrogenation to C2+hydrocarbons operated at low temperature and atmospheric pressure in a dielectric barrier discharge (DBD) packed-bed reactor. Plasma without catalyst produces mainly CO (over 80% selectivity), while CH4becomes the main product when plasma is coupled with the alumina-supported Co catalyst. Interestingly, by simply changing the catalyst-bed configuration within the plasma discharge zone, more C2+hydrocarbons are selectively produced. High C2+hydrocarbons selectivity of 46% atca.74% CO2conversion is achieved when operated at the furnace temperature of 25 °C and 10 W DBD plasma. The possible origin of C2+formation and the significance of catalyst-bed configuration are discussed.",

author = "Jiajie Wang and AlQahtani, {Mohammad S.} and Xiaoxing Wang and Knecht, {Sean D.} and Bil{\'e}n, {Sven G.} and Chunshan Song and Wei Chu",

note = "Funding Information: This work is financially supported by the Pennsylvania State University and EMS Energy Institute Seed Grant. J.W. also acknowledges the financial support from the Chinese Scholarship Council (CSC). M.S.Q. gratefully acknowledges the PhD scholarship from Saudi Aramco. The authors would like to thank Dr Na Liu and Dr Wenjia Wang for their helpful discussion and advices. Publisher Copyright: {\textcopyright} The Royal Society of Chemistry 2021.",

year = "2021",

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doi = "10.1039/d0gc03779f",

language = "English (US)",

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TY - JOUR

T1 - One-step plasma-enabled catalytic carbon dioxide hydrogenation to higher hydrocarbons

T2 - significance of catalyst-bed configuration

AU - Wang, Jiajie

AU - AlQahtani, Mohammad S.

AU - Wang, Xiaoxing

AU - Knecht, Sean D.

AU - Bilén, Sven G.

AU - Song, Chunshan

AU - Chu, Wei

N1 - Funding Information: This work is financially supported by the Pennsylvania State University and EMS Energy Institute Seed Grant. J.W. also acknowledges the financial support from the Chinese Scholarship Council (CSC). M.S.Q. gratefully acknowledges the PhD scholarship from Saudi Aramco. The authors would like to thank Dr Na Liu and Dr Wenjia Wang for their helpful discussion and advices. Publisher Copyright: © The Royal Society of Chemistry 2021.

PY - 2021/2/21

Y1 - 2021/2/21

N2 - Effectively converting CO2into fuels and value-added chemicals remains a major challenge in catalysis, especially under mild conditions. In this study, we report a one-step plasma-enabled catalytic process for CO2hydrogenation to C2+hydrocarbons operated at low temperature and atmospheric pressure in a dielectric barrier discharge (DBD) packed-bed reactor. Plasma without catalyst produces mainly CO (over 80% selectivity), while CH4becomes the main product when plasma is coupled with the alumina-supported Co catalyst. Interestingly, by simply changing the catalyst-bed configuration within the plasma discharge zone, more C2+hydrocarbons are selectively produced. High C2+hydrocarbons selectivity of 46% atca.74% CO2conversion is achieved when operated at the furnace temperature of 25 °C and 10 W DBD plasma. The possible origin of C2+formation and the significance of catalyst-bed configuration are discussed.

AB - Effectively converting CO2into fuels and value-added chemicals remains a major challenge in catalysis, especially under mild conditions. In this study, we report a one-step plasma-enabled catalytic process for CO2hydrogenation to C2+hydrocarbons operated at low temperature and atmospheric pressure in a dielectric barrier discharge (DBD) packed-bed reactor. Plasma without catalyst produces mainly CO (over 80% selectivity), while CH4becomes the main product when plasma is coupled with the alumina-supported Co catalyst. Interestingly, by simply changing the catalyst-bed configuration within the plasma discharge zone, more C2+hydrocarbons are selectively produced. High C2+hydrocarbons selectivity of 46% atca.74% CO2conversion is achieved when operated at the furnace temperature of 25 °C and 10 W DBD plasma. The possible origin of C2+formation and the significance of catalyst-bed configuration are discussed.

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One-step plasma-enabled catalytic carbon dioxide hydrogenation to higher hydrocarbons: significance of catalyst-bed configuration

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