A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design
The utilization of captured CO2 for chemical synthesis could play an important role in reducing CO2 emissions. Higher alcohols stand out among various products of CO2 reduction due to high market prices and diverse applications, e.g., as fuel additives. However, developing catalysts for this reactio...
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sg-ntu-dr.10356-1732462024-01-22T02:19:16Z A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design Sheng, Yao Polynski, Mikhail V. Eswaran, Mathan K. Zhang, Bikun Lim, Alvin M. H. Zhang, Lili Jiang, Jianwen Liu, Wen Kozlov, Sergey M. School of Chemistry, Chemical Engineering and Biotechnology Cambridge Centre for Advanced Research and Education Engineering::Chemical engineering Catalysis Alcohols The utilization of captured CO2 for chemical synthesis could play an important role in reducing CO2 emissions. Higher alcohols stand out among various products of CO2 reduction due to high market prices and diverse applications, e.g., as fuel additives. However, developing catalysts for this reaction requires a profound understanding of the reaction mechanisms and catalyst design principles, which are discussed in the present review. Depending on the catalytic sites, higher alcohol synthesis could proceed via vastly different pathways. Herein, we outline how various proposed reaction mechanisms lead to different catalyst design strategies for optimizing the rate of CO2 conversion into reactive C1 intermediates (CO, CHx, CHxO, and HCOO) and their coupling into C2+ intermediates that are eventually converted into higher alcohols. Lastly, we discuss knowledge gaps in achieving rational catalyst design for higher alcohol synthesis and the breakthrough potential of machine-learning techniques for catalyst discovery. Agency for Science, Technology and Research (A*STAR) National Research Foundation (NRF) This work is supported by Agency for Science, Technology and Research (A*STAR) through Low Carbon Energy Research Finding Initiative (LCERFI01–0033 | U2102d2006). Y.S and W.L extend their acknowledgement of financial support by National Research Foundation of Singapore under its Campus for Research Enterprise and Technological Excellence (CREATE) programme. 2024-01-22T02:19:16Z 2024-01-22T02:19:16Z 2024 Journal Article Sheng, Y., Polynski, M. V., Eswaran, M. K., Zhang, B., Lim, A. M. H., Zhang, L., Jiang, J., Liu, W. & Kozlov, S. M. (2024). A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design. Applied Catalysis B: Environmental, 343, 123550-. https://dx.doi.org/10.1016/j.apcatb.2023.123550 0926-3373 https://hdl.handle.net/10356/173246 10.1016/j.apcatb.2023.123550 2-s2.0-85178378144 343 123550 en LCERFI01–0033 U2102d2006 Applied Catalysis B: Environmental © 2023 Elsevier B.V. All rights reserved. |
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Engineering::Chemical engineering Catalysis Alcohols |
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Engineering::Chemical engineering Catalysis Alcohols Sheng, Yao Polynski, Mikhail V. Eswaran, Mathan K. Zhang, Bikun Lim, Alvin M. H. Zhang, Lili Jiang, Jianwen Liu, Wen Kozlov, Sergey M. A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design |
| description |
The utilization of captured CO2 for chemical synthesis could play an important role in reducing CO2 emissions. Higher alcohols stand out among various products of CO2 reduction due to high market prices and diverse applications, e.g., as fuel additives. However, developing catalysts for this reaction requires a profound understanding of the reaction mechanisms and catalyst design principles, which are discussed in the present review. Depending on the catalytic sites, higher alcohol synthesis could proceed via vastly different pathways. Herein, we outline how various proposed reaction mechanisms lead to different catalyst design strategies for optimizing the rate of CO2 conversion into reactive C1 intermediates (CO, CHx, CHxO, and HCOO) and their coupling into C2+ intermediates that are eventually converted into higher alcohols. Lastly, we discuss knowledge gaps in achieving rational catalyst design for higher alcohol synthesis and the breakthrough potential of machine-learning techniques for catalyst discovery. |
| author2 |
School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Sheng, Yao Polynski, Mikhail V. Eswaran, Mathan K. Zhang, Bikun Lim, Alvin M. H. Zhang, Lili Jiang, Jianwen Liu, Wen Kozlov, Sergey M. |
| format |
Article |
| author |
Sheng, Yao Polynski, Mikhail V. Eswaran, Mathan K. Zhang, Bikun Lim, Alvin M. H. Zhang, Lili Jiang, Jianwen Liu, Wen Kozlov, Sergey M. |
| author_sort |
Sheng, Yao |
| title |
A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design |
| title_short |
A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design |
| title_full |
A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design |
| title_fullStr |
A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design |
| title_full_unstemmed |
A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design |
| title_sort |
review of mechanistic insights into co₂ reduction to higher alcohols for rational catalyst design |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173246 |
| _version_ |
1789483224197496832 |