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4,774 results on '"CO2 hydrogenation to methanol"'

2. High efficient sunlight-driven CO2 hydrogenation to methanol over NiZn intermetallic catalysts under atmospheric pressure

Author

Han, Linjia, Meng, Fanqi, Bai, Xianhua, Wu, Qixuan, Luo, Yanhong, Shi, Jiangjian, Li, Yaguang, Li, Dongmei, and Meng, Qingbo

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

The synthesis of solar methanol through direct CO2 hydrogenation using solar energy is of great importance in advancing a sustainable energy economy. In this study, non-precious NiZn intermetallic/ZnO catalyst is reported to catalyze the hydrogenation of CO2 to methanol using sunlight irradiation (1sun). The NiZn-ZnO interface is identified as the active site to stabilize the key intermediates of HxCO*. At ambient pressure, the NiZn-ZnO catalyst demonstrates a methanol production rate of 127.5 umol g-1h-1 from solar driven CO2 hydrogenation, with a remarkable 100% selectivity towards methanol in the total organic products. Notably, this production rate stands as the highest record for photothermic CO2 hydrogenation to methanol in continuous-flow reactors with sunlight as the only requisite energy input. This discovery not only paves the way for the development of novel catalysts for CO2 hydrogenation to methanol but also marks a significant stride towards a full solar-driven chemical energy storage.

Published
2024

9. Mechanistic exploration of non-thermal plasma-enhanced Cu-catalyzed CO2 hydrogenation to methanol

Author

Yumin CHEN, Yongheng DONG, Chengjing SHI, Longkun SUN, Bingxin ZHU, Bing LI, Yang LIU, and Huaichun ZHOU

Subjects
plasma catalysis, co2 hydrogenation, green methanol, kinetic calculation, emission spectrum, Geology, QE1-996.5, Mining engineering. Metallurgy, TN1-997
Abstract

Combining CO2 and green hydrogen to produce methanol can simultaneously realize CO2 conversion and green hydrogen storage. Methanol can be used as a green low-carbon fuel or industrial platform product for large-scale application, which is of great significance to promote the further development of Carbon Capture, Utilization and Storage (CCUS) technology. Non-thermal plasma (NTP) can activate CO2 under mild conditions for hydrogenation reaction and obtain specific products such as methanol by combining with catalysts to tailor the reaction routes, but the underlying reaction mechanism is still unclear. Based on this, the reaction mechanism and process coupling laws of the NTP-enhanced CO2 hydrogenation with assistance of Cu/γ-Al2O3 for methanol production were investigated by combining hydrogenation experiments in a dielectric barrier discharge (DBD) reactor with continuously-pulsed discharge plasma simulations. The experiments investigation showed that 18.74% CO2 conversion and 36.28% CH3OH selectivity could be achieved by combining NTP and 10% Cu/γ-Al2O3 at 80 ℃ and 0.1 MPa. The on-line discharge parameters monitoring and in-situ emission spectroscopy (OES) showed that the localized discharge was enhanced by Cu/γ-Al2O3, which increased the average electron energy and density, thus promote the CO and H generation and their surface consumption reaction, resulting in the weakening of spectral intensity. Furthermore, the sensitivity and ROP analyses indicated that the active substances such as H and CO in NTP promoted methanol generation efficiently by alternating the corresponding L-H routes, which usually had higher energy barriers, via E-R reactions such as CO2(S)+H→COOH(S), CO+H(S)→HCO(S), CO(S)+H→HCO(S), and CH3O(S)+H→CH3OH(S). The reaction pathways analysis revealed that the formate (HCOO*) pathway was the main pathway for methanol generation on the Cu/γ-Al2O3 surface, where the reaction CH3O(S)+H(S)→CH3OH(S)+Cu(S) was the rate-limiting step. The generation of CO(S) via the CO2(S)→COOH(S)→CO(S) in the RWGS+CO hydrogenation pathway and its rapid desorption played a vital role in reducing CH3OH selectivity. Uncertainty analysis demonstrated that although increasing the CO2 adsorption rate could effectively improve its conversion, but would not increase CO selectivity when H(S) was insufficient. The optimal CO2 and H2 adsorption rate ratio was predicated to be γ(H2)/γ(CO2)=7~8. Improving CO(S) adsorption stability and enhancing H2 electron collisional dissociation to promote H generation could promote reactions of CO(S)→HCO(S) and CH3O(S)→CH3OH(S), thus facilitated a CO2 conversion of 27.4% and CH3OH selectivity of 51% synergistically.

Published
2024
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10. The effect of zirconia as a promoter on Cu/MOF-5 catalysts for CO2 hydrogenation to methanol

Author

Amanda S. Mbhele, Mduduzi N. Cele, Mzamo L. Shozi, and Holger B. Friedrich

Subjects
Copper, MOF-5, Zirconium, CO2 hydrogenation, Methanol, Chemical engineering, TP155-156
Abstract

The rise in carbon dioxide concentration is a primary anthropogenic source of severe climate change and ecological issues. Catalytic hydrogenation of CO2 into value-added chemicals and fuels including methanol is one of the attractive environmentally friendly ways to valorize carbon-containing feedstock and reduce global CO2 emissions. However, enhancing catalytic activity to achieve high methanol yield and selectivity while maintaining stability remains a major challenge. This study investigated the promotion of Cu/MOF-5 catalysts with varying loadings of ZrO₂ to determine its effects on catalytic performance in CO₂ hydrogenation. The copper loading was kept constant while the ZrO₂ content on the MOF-5 support was varied via the impregnation method. The addition of ZrO₂ was found to influence the BET surface area, suggesting the presence of amorphous ZrO₂, as its crystalline phases were not detected in x-ray diffractograms. Catalytic results demonstrated that ZrO₂ addition enhanced the catalytic activity, with increased CO₂ conversion up to 13.2 %. The results showed a correlation between catalytic performance and the reducibility of the active metal, driven by the amount of ZrO₂ present. The catalyst with the highest ZrO₂ loading exhibited the best performance, attributed to its increased surface area and enhanced reducibility. Under optimized conditions (GHSV of 1350 h⁻¹, temperature of 200 °C, and pressure of 30 bar), the catalyst achieved 100 % methanol selectivity. This study underscores the significant role of ZrO₂ as a promoter in enhancing the activity and selectivity of Cu/MOF-5 catalysts, providing critical insights into the design of efficient catalytic systems for CO₂ hydrogenation.

Published
2024
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