| Title | Catalytic CO2 conversion to C1 value-added products: Review on latest catalytic and process developments |
|---|---|
| ID_Doc | 24861 |
| Authors | Yusuf, N; Almomani, F; Qiblawey, H |
| Title | Catalytic CO2 conversion to C1 value-added products: Review on latest catalytic and process developments |
| Year | 2023 |
| Published | |
| Abstract | With the increase in CO2 emissions in the last decades, CO2 capture and storage and CO2 capture and utilization technologies have been interesting topics in literature and industry. CO2 direct utilization for oil gas recovery is a mature utilization route in the oil and gas industry. CO2 is the focus of many technological and academic studies for its potential as a source of carbon for producing value-added chemical products and synthetic fuels. CO2 utilization technologies are grouped based on the production route, such as electrochemical, catalytic, photo -catalytic, photosynthetic, biological, and depolymerization. This review discusses the latest technological in-novations in catalyst developments for direct CO2 utilization to C1 value-added products and fuels. Amongst the various potential products, CO2 conversion to dimethyl carbonates, methanol, formic acid, syngas, and methane using different homogenous and heterogeneous catalytic systems was discussed. The most recent advancements for process exploitations were highlighted for each utilization route to evaluate the maturity of the proposed systems technically and economically. The review revealed that thermally-driven CO2 catalytic conversion to methanol, synthesis gas and methane are the most promising for industrial deployment. Furthermore, Green hydrogen and the cost of energy production are the key obstacles to large-scale deployments of CO2 utilization. However, supported by the latest advancements in renewable energy production, the discussed utilization routes would be more applicable in the near future. |
| https://doi.org/10.1016/j.fuel.2023.128178 |
Similar Articles
| ID | Score | Article |
|---|---|---|
27468
|
Ravanchi, MT; Sahebdelfar, S Catalytic conversions of CO2 to help mitigate climate change: Recent process developments(2021) | |
| 8479
|
Ruiz-López, E; Gandara-Loe, J; Baena-Moreno, F; Reina, TR; Odriozola, JA Electrocatalytic CO2 conversion to C2 products: Catalysts design, market perspectives and techno-economic aspects(2022) | |
| 13490
|
Merkouri, LP; Reina, TR; Duyar, MS Closing the Carbon Cycle with Dual Function Materials(2021)Energy & Fuels, 35, 24 | |
| 19614
|
Centi, G; Perathoner, S Chemistry and energy beyond fossil fuels. A perspective view on the role of syngas from waste sources(2020) | |
| 29125
|
Pan, SY; Chiang, PC; Pan, WB; Kim, H Advances in state-of-art valorization technologies for captured CO2 toward sustainable carbon cycle(2018)Critical Reviews In Environmental Science And Technology, 48.0, 5 | |
| 24215
|
Perathoner, S; Van Geem, KM; Marin, GB; Centi, G Reuse of CO2 in energy intensive process industries(2021)Chemical Communications, 57, 84 | |
| 19949
|
Tommasi, M; Degerli, SN; Ramis, G; Rossetti, I Advancements in CO2 methanation: A comprehensive review of catalysis, reactor design and process optimization(2024) | |
| 10332
|
Zhong, X; Peng, HJ; Xia, C; Liu, XY Recent advances in upgrading CO2 to C3+ products via electrochemical and complementary engineering(2024)Journal Of Materials Chemistry A, 12, 31 | |
| 10603
|
Alli, YA; Oladoye, PO; Ejeromedoghene, O; Bankole, OM; Alimi, OA; Omotola, EO; Olanrewaju, CA; Philippot, K; Adeleye, AS; Ogunlaja, AS Nanomaterials as catalysts for CO2 transformation into value-added products: A review(2023) | |
| 9036
|
Falcinelli, S Fuel production from waste CO2 using renewable energies(2020) |