Roles of Oxygen Vacancies in CeO<sub>2</sub> Nanostructures for Catalytic Aerobic Cyclohexane Oxidation

Li, Yingwei; Li, Hao; Li, Kexin; Wang, Ruirui; Liu, Ruixia

doi:10.1021/acsanm.3c02147

Cited by 11 publications

(6 citation statements)

References 67 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The two peaks desorbed below 450 °C are usually considered as ROS (such as O 2 2– , O 2 – , or O – ) of Co 3 O 4 catalyst, and the active oxygen on the surface of the catalyst plays an important role in promoting the catalytic oxidation reaction . ROS, with a peak at 100 °C, has the lowest desorption temperature, which is easy to obtain and participate in cyclohexane oxidation conditions, and O 2 – is an oxygen that can be obtained by obtaining only one electron . It is considered that the desorbed O 2 – at this temperature is the main active species involved in cyclohexane oxidation.…”

Section: Resultsmentioning

confidence: 99%

“…− is an oxygen that can be obtained by obtaining only one electron. 34 It is considered that the desorbed O 2 − at this temperature is the main active species involved in cyclohexane oxidation. Compared with Co 3 O 4 -P, the O 2 desorption peak of Co 3 O 4 -C below 450 °C obviously moves to the low-temperature region, which means that the surface oxygen vacancies are more likely to activate the adsorbed oxygen, and the nanocage framework of Co 3 O 4 -C can construct an internal and external concentration gradient, resulting in a limited space to provide a local high concentration of O 2 when adsorption and desorption occur in the cage, resulting in easier activation of oxygen to form ROS.…”

Section: Surface Chemical States Of Catalystsmentioning

confidence: 99%

See 1 more Smart Citation

Prussian Blue Analogue-Derived Co₃O₄ as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Wei,

Li,

Zhong

et al. 2024

ACS Appl. Mater. Interfaces

Self Cite

View full text Add to dashboard Cite

Selective conversion of inert C−H bonds in alkanes into high-valueadded functional groups (alcohols, ketones, carboxylic acids, etc.) plays a vital role in establishing a green and sustainable chemical industry. Catalytic selective oxidation of cyclohexane to KA oil (cyclohexanol and cyclohexanone) is a typical representative of alkane functionalization. In this work, hollow cage-like Co 3 O 4 (Co 3 O 4 -C) and particle Co 3 O 4 (Co 3 O 4 -P) were synthesized by calcining two types of Prussian blue analogues (PBAs), which were used to catalyze the selective oxidation of cyclohexane. The Co 3 O 4 -C predominantly exposed (311) crystal plane is easier to adsorb cyclohexane than Co 3 O 4 -P, which is beneficial to shorten the induction period, accelerate the reaction rate, and improve the conversion. Consequently, Co 3 O 4 -C displayed a 10% conversion of cyclohexane within 1 h, and the KA oil selectivity reached 90%. The Co 3 O 4 -P exposed (220) crystal plane has a higher molar percentage of oxygen vacancies and more active oxygen species, as well as a strong cyclohexanone adsorption capacity, which is conducive to the deep oxidation of cyclohexanone to adipic acid and other diacid products. The mechanism analysis of cyclohexane oxidation catalyzed by PBA-based Co 3 O 4 shows that it exemplifies the feasibility to tailor the surface of catalysts by modulating the PBAs, which ultimately influences their reaction performance for accelerating the reaction and maintaining high cyclohexane conversion and KA oil selectivity.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Surface Chemical States Of Catalystsmentioning

confidence: 99%

Prussian Blue Analogue-Derived Co₃O₄ as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Wei,

Li,

Zhong

et al. 2024

ACS Appl. Mater. Interfaces

Self Cite

View full text Add to dashboard Cite

show abstract

“…Aerobic oxidation of hydrocarbons is of great importance for producing value-added oxygenated chemicals in the modern chemical industry. , Among them, the selective oxidation of saturated alkanes under mild conditions is much more difficult due to the laborious activation of inert C–H bonds and facile deep oxidation of reactive target products. , For example, cyclohexane liquid-phase oxidation into cyclohexanol, cyclohexanone, and adipic acid, a typical hydrocarbon resource high-value utilization process, is the crucial technology to manufacture polyamide 6 and 6,6 in industry. , In general, the oxidation of cyclohexane with molecular oxygen is performed in the presence of soluble metal salts at the temperature of above 150 °C, wherein the cyclohexane conversion is controlled below 4% to maintain the overall selectivity toward cyclohexanol and cyclohexanone at a relatively high level of 70–85%. , The serious energy consumption and increased environmental concerns call for benign oxidation including high oxidation efficiency, recoverable catalysts, molecular oxygen as the green oxidant, and solvent-free. In the past decade, the solvent-free cyclohexane oxidation has been paid more attention in developing new types of heterogeneous catalysts. , Diverse metal and metal oxide catalysts have been developed and applied into the catalytic oxidation of cyclohexane. − Among them, metallic cobalt and cobalt oxides (e.g., Co 3 O 4 , LaCoO 3 , and Co-MgAlO) with the adjustable structure properties are widely considered as the promising catalysts for the cyclohexane oxidation by adsorbing and activating O 2 molecules or C–H bonds in cyclohexane on the active sites. − Nevertheless, Unnarkat et al and Yuan et al found that organic acids and water generated in the course of the cyclohexane oxidation were inclined to adsorb on the active sites, giving rise to the inevitable deactivation of the catalysts. , Thus, it can be found that there are two core issues to be addressed for the heterogeneous catalytic oxidation of cyclohexane: (i) to ensure the acceptable product selectivity (above 90%) at the relatively high conversion (above 15%) under mild reaction conditions and (ii) to construct the robust catalytic structure against the deactivation during oxidation.…”

Section: Introductionmentioning

confidence: 99%

Curved Surface of Graphitic Carbon Nitride Boosting Cyclohexane Oxidation over Single-Atom Catalysts

Xu,

Yu,

Shi

et al. 2024

ACS Appl. Nano Mater.

View full text Add to dashboard Cite

Although single metal sites on graphitic carbon nitride (g-C3N4) are extensively employed in the catalysis field, the related study is based on the flat g-C3N4 surface model, which is far beyond the reality of the curved structure involved in g-C3N4. Herein, g-C3N4 nanorods with diameters of 9.0 and 7.0 nm are synthesized via the hard template approach to support single-atom Co for the catalytic oxidation of cyclohexane. Comprehensive characterizations, combined with theoretical calculations, find that the curved structure would broaden the space of g-C3N4 interlayers, modulate the electronic structure, and reduce the coordination number of atomic Co. The mechanism study reveals that compared with Co atoms on a flat g-C3N4 surface, the low-coordinated Co atoms anchored on a curved g-C3N4 surface are capable of enhancing the reactant adsorption and facilitating the oxygen dissociation, thereby boosting the catalytic cyclohexane oxidation. The cyclohexane conversion on resultant Co/g-C3N4-9 nm reaches up to 22.4% at the overall selectivity of above 95% under mild reaction conditions, outperforming state-of-the-art nonprecious metal-based catalysts. The present work not only offers a synthesis strategy of the effective single-atom metal catalysts for the cyclohexane oxidation but also sheds light on the origin of the enhanced catalytic performance of curved g-C3N4-based catalysts.

show abstract

“…Song et al 16 reported that the synergistic effect between CeO 2 and MnO x could provide more amounts of oxygen vacancy, the highest concentration of Mn 3+ , and the highest Ce 3+ contents, which resulted in an outstanding oxygen mobility, causing the improvement of catalytic activity. Li et al 17 reported that cerium dioxide nanoparticles have the most active surface oxygen vacancies that determine the catalytic activity and have the strongest activation capacity, contributing to high reactivity under extremely inert conditions. The roasting process of vanadium slag is a typical oxidation process, and the activation of molecular oxygen has emerged to be an important step.…”

Section: Introductionmentioning

confidence: 99%

Promoting the Calcified Roasting of Vanadium Slag Based on the CeO₂-Catalytic Oxidation Mechanism

Xu,

Tang,

Chen

et al. 2024

ACS Omega

View full text Add to dashboard Cite

Calcification roasting−acid leaching is a clean, efficient, and environmentally friendly process, but in the roasting process, the local temperature is often too high, the heat release is not timely, and the heat transfer is blocked. Furthermore, the material is easy to sinter, which affects the final vanadium extraction effect. In this paper, a small amount of CeO 2 was introduced in the roasting process of vanadium slag to promote the calcified roasting. The results showed that the vanadium leaching rate reached 93.17% with the addition of 0.1 wt % CeO 2 at a roasting temperature of 750 °C, which was higher than that obtained without CeO 2 addition (90.00%). The results of XPS, XRD, and SEM-EDS analyses confirmed that adding CeO 2 to the roasted clinker significantly increased the proportion of pentavalent vanadium to the total vanadium by up to 28.64%. O 2 -TPD analysis revealed an enhanced chemisorbed oxygen with the CeO 2 -assisted roasting, indicated the activation of oxygen by CeO 2 , and resulted in an enhanced oxidation of vanadium. The work in this paper establishes an alternative route for catalytic oxidation-enhanced vanadium slag roasting, which can improve the utilization of vanadium slag at relatively lower temperatures under the action of CeO 2 and is of positive significance in solving the problems of sintering and energy consumption in the roasting process.

show abstract

Roles of Oxygen Vacancies in CeO₂ Nanostructures for Catalytic Aerobic Cyclohexane Oxidation

Cited by 11 publications

References 67 publications

Prussian Blue Analogue-Derived Co₃O₄ as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Prussian Blue Analogue-Derived Co₃O₄ as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Curved Surface of Graphitic Carbon Nitride Boosting Cyclohexane Oxidation over Single-Atom Catalysts

Promoting the Calcified Roasting of Vanadium Slag Based on the CeO₂-Catalytic Oxidation Mechanism

Contact Info

Product

Resources

About

Roles of Oxygen Vacancies in CeO2 Nanostructures for Catalytic Aerobic Cyclohexane Oxidation

Cited by 11 publications

References 67 publications

Prussian Blue Analogue-Derived Co3O4 as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Prussian Blue Analogue-Derived Co3O4 as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Curved Surface of Graphitic Carbon Nitride Boosting Cyclohexane Oxidation over Single-Atom Catalysts

Promoting the Calcified Roasting of Vanadium Slag Based on the CeO2-Catalytic Oxidation Mechanism

Contact Info

Product

Resources

About

Roles of Oxygen Vacancies in CeO₂ Nanostructures for Catalytic Aerobic Cyclohexane Oxidation

Prussian Blue Analogue-Derived Co₃O₄ as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Prussian Blue Analogue-Derived Co₃O₄ as Catalysts for Enhanced Selective Oxidation of Cyclohexane Using Molecular Oxygen

Promoting the Calcified Roasting of Vanadium Slag Based on the CeO₂-Catalytic Oxidation Mechanism