Improving the Cu/ZnO-Based Catalysts for Carbon Dioxide Hydrogenation to Methanol, and the Use of Methanol As a Renewable Energy Storage Media

Etim, U.J.; Song, Yibing; Zhong, Ziyi

doi:10.3389/fenrg.2020.545431

Cited by 63 publications

(48 citation statements)

References 214 publications

(324 reference statements)

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“…13 The catalyst activity is still under investigation, and recent publications demonstrate that there exists the potential for improving the catalyst formulation also in the perspective of CO 2 hydrogenation to methanol. 14,15 Deepening the analysis of new technologies and apparatus (Figure 5), it is worth noting that most of the innovations in the last three decades deal with feedstock. This is mainly due to the change of raw materials used in syngas production, first from fossil to renewable sources and, then, to CO 2 for direct conversion.…”

Section: ■ Introductionmentioning

confidence: 99%

Century of Technology Trends in Methanol Synthesis: Any Need for Kinetics Refitting?

Bisotti

Fedeli

Prifti

et al. 2021

Ind. Eng. Chem. Res.

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Recently, methanol has gained increasing attention thanks to the variety of feedstocks suitable for its production and its low environmental impact granting the molecule a key role in future economic roadmaps as in Olah’s development model. Nowadays, fossil sources are not the exclusive sources to produce syngas: biogas is a promising alternative, leading to less severe operating conditions and smaller plant scales. The most widespread kinetic models for methanol synthesis, namely, the Graaf and the Vanden Bussche–Froment models, will be proven not to be fully adequate in characterizing these conditions. A robust refit is shown to outperform predictions from conventional models and follow recent trends in process operations. The refitted Graaf model is more flexible on the operating conditions and feed compositions, removing also some infeasible discontinuities present in conventional models. The final result is a more generalized and accurate Graaf’s model for methanol synthesis on CZA catalysts.

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Section: ■ Introductionmentioning

confidence: 99%

Century of Technology Trends in Methanol Synthesis: Any Need for Kinetics Refitting?

Bisotti

Fedeli

Prifti

et al. 2021

Ind. Eng. Chem. Res.

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“…Yu et al [96] demonstrated through spin-polarized DFT calculations that adsorption and dissociation of CO 2 was dependent on the Co particle size. They showed that Co 55 nanoclusters had the highest CO 2 dissociation activity in comparison to Cu-based materials have gained much attention in the CO 2 conversion process due to their wide applicability in the different conversion processes and low cost [12,97]. Despite these and other massive studies, the activation of CO 2 on Cu catalysts is still an issue due to the poor understanding of its mechanism.…”

Section: Co 2 Activation On Representative Pure Metalsmentioning

confidence: 99%

Impacts of the Catalyst Structures on CO2 Activation on Catalyst Surfaces

2021

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Utilizing CO2 as a sustainable carbon source to form valuable products requires activating it by active sites on catalyst surfaces. These active sites are usually in or below the nanometer scale. Some metals and metal oxides can catalyze the CO2 transformation reactions. On metal oxide-based catalysts, CO2 transformations are promoted significantly in the presence of surface oxygen vacancies or surface defect sites. Electrons transferable to the neutral CO2 molecule can be enriched on oxygen vacancies, which can also act as CO2 adsorption sites. CO2 activation is also possible without necessarily transferring electrons by tailoring catalytic sites that promote interactions at an appropriate energy level alignment of the catalyst and CO2 molecule. This review discusses CO2 activation on various catalysts, particularly the impacts of various structural factors, such as oxygen vacancies, on CO2 activation.

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“…Different types of catalysts have been investigated for the thermocatalytic hydrogenation of CO 2 to methanol, including supported metal [ 8 , 9 ] and metal oxide [ 10 , 11 ] catalysts. Cu-based catalysts have been reported to have the best activity for methanol production under industrially relevant conditions (5–10 MPa and 200–300 °C) [ 12 , 13 ]. The Cu-ZnO-Al 2 O 3 catalyst prepared via the co-precipitation method is the industrial catalyst used for methanol production from CO + H 2 ; thus, the Cu-ZnO-based catalysts are widely investigated for CO 2 hydrogenation to methanol as well [ 14 , 15 ].…”

Section: Introductionmentioning

confidence: 99%

CO2 Activation and Hydrogenation on Cu-ZnO/Al2O3 Nanorod Catalysts: An In Situ FTIR Study

et al. 2022

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CuZnO/Al2O3 is the industrial catalyst used for methanol synthesis from syngas (CO + H2) and is also promising for the hydrogenation of CO2 to methanol. In this work, we synthesized Al2O3 nanorods (n-Al2O3) and impregnated them with the CuZnO component. The catalysts were evaluated for the hydrogenation of CO2 to methanol in a fixed-bed reactor. The support and the catalysts were characterized, including via in situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS). The study of the CO2 adsorption, activation, and hydrogenation using in situ DRIFT spectroscopy revealed the different roles of the catalyst components. CO2 mainly adsorbed on the n-Al2O3 support, forming carbonate species. Cu was found to facilitate H2 dissociation and further reacted with the adsorbed carbonates on the n-Al2O3 support, transforming them to formate or additional intermediates. Like the n-Al2O3 support, the ZnO component contributed to improving the CO2 adsorption, facilitating the formation of more carbonate species on the catalyst surface and enhancing the efficiency of the CO2 activation and hydrogenation into methanol. The synergistic interaction between Cu and ZnO was found to be essential to increase the space–time yield (STY) of methanol but not to improve the selectivity. The 3% CuZnO/n-Al2O3 displayed improved catalytic performance compared to 3% Cu/n-Al2O3, reaching a CO2 conversion rate of 19.8% and methanol STY rate of 1.31 mmolgcat−1h−1 at 300 °C. This study provides fundamental and new insights into the distinctive roles of the different components of commercial methanol synthesis catalysts.

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Improving the Cu/ZnO-Based Catalysts for Carbon Dioxide Hydrogenation to Methanol, and the Use of Methanol As a Renewable Energy Storage Media

Cited by 63 publications

References 214 publications

Century of Technology Trends in Methanol Synthesis: Any Need for Kinetics Refitting?

Century of Technology Trends in Methanol Synthesis: Any Need for Kinetics Refitting?

Impacts of the Catalyst Structures on CO2 Activation on Catalyst Surfaces

CO2 Activation and Hydrogenation on Cu-ZnO/Al2O3 Nanorod Catalysts: An In Situ FTIR Study

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