Plasma catalysis: a feasible solution for carbon dioxide valorization?

This review highlighted the current ongoing research in plasma technology and why this process needs to be explored in synergy with the other available/researched technologies worldwide. It provides a broad outlook to study the various elements of non-thermal plasma for CO 2 conversion. Most commonl...

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Bibliographic Details
Published in:Clean technologies and environmental policy 2021-12, Vol.23 (10), p.2789-2811
Main Authors: Anoop, N., Sundaramurthy, Suresh, Jha, Jay Mant, Chandrabalan, Sasikumar, Singh, Nimmi, Verma, Jyoti, Parvatalu, Damaraju, Katti, Sanjeev
Format: Article
Language:English
Subjects:
Carbon dioxide
Catalysis
Catalysts
Catalytic converters
Conversion
Dielectric barrier discharge
Earth and Environmental Science
Electric arcs
Energy development
Energy efficiency
Environment
Environmental Economics
Environmental Engineering/Biotechnology
Environmental policy
Flow rates
Flow velocity
Gas flow
Gliding
Industrial and Production Engineering
Industrial applications
Industrial Chemistry/Chemical Engineering
Plasma
Reactors
Reforming
Review
Selectivity
State-of-the-art reviews
Sustainable Development
Thermal plasmas
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Summary:This review highlighted the current ongoing research in plasma technology and why this process needs to be explored in synergy with the other available/researched technologies worldwide. It provides a broad outlook to study the various elements of non-thermal plasma for CO 2 conversion. Most commonly used reactors such as dielectric barrier discharge (DBD) plasma, microwave (MW) plasma, and gliding arc (GA) plasma are described with their operational challenges. It covers the laboratory-scale reactor designs, characterization, the overall efficiencies, the physical and chemical interplay between plasma and catalysis, as well as many of the recent efforts to improve the reaction efficiency. Multiple configurations of plasma reactors along with the effect of operating parameters such as gas flow rate, power input, diluting gas, and others on conversion and energy efficiency are reviewed in this paper. Different catalytic materials and their effect on conversion and energy efficiency are also explored. This review outlines the state-of-the-art development of the plasma catalysis process for CO 2 conversion, including CO 2 splitting and briefly discussing the mechanistic insights into CO 2 hydrogenation and reforming. Additionally, the role and need for the intrinsic rational design of catalyst composition and structure in determining the selectivity of CO 2 conversion is also deliberated. A perspective on current bottlenecks and opportunities for the advancement in development of next-generation novel catalysts for plasma catalysis for industrial applications is also presented. Graphic abstract
ISSN:1618-954X
1618-9558
DOI:10.1007/s10098-021-02203-y