Water‐Assisted Homolytic Dissociation of Propyne on a Reduced Ceria Surface

Zhong, Jiuping; Han, Zhongkang; Werner, Kristin; Li, Xiaoyan; Gao, Yi; Shaikhutdinov, Shamil K.; Freund, Hans‐Joachim

doi:10.1002/anie.201914271

Cited by 20 publications

(18 citation statements)

References 49 publications

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“…Additionally, the rate-determining step or possible reaction pathway of reactions over CeO 2 -based catalysts can be identified by the reaction energy profiles via theoretical calculations. ,,,,, For example, during the oxidation of (5-(1,3-dioxan-2-yl) furan-2-yl)methanol (PD-HMF) into FDCA over the CeO 2 -supported Au catalyst, DFT calculations identify two crucial steps in the reaction mechanism, including the partial hydrolysis of the acetal into 5-formyl-2-furan carboxylic acid involving OH – and Lewis acid sites on CeO 2 , and subsequent oxidative dehydrogenation of the in situ generated hemiacetal involving Au nanoparticles …”

Section: Reaction Mechanism Studiesmentioning

confidence: 99%

“…244 Additionally, the rate-determining step or possible reaction pathway of reactions over CeO 2 -based catalysts can be identified by the reaction energy profiles via theoretical calculations. 160,207,212,234,289,416 For example, during the oxidation of (5-(1,3-dioxan-2-yl) furan-2-yl)methanol (PD-HMF) into FDCA over the CeO 2 -supported Au catalyst, DFT calculations identify two crucial steps in the reaction mechanism, including the partial hydrolysis of the acetal into 5-formyl-2-furan carboxylic acid involving OH − and Lewis acid sites on CeO 2 , and subsequent oxidative dehydrogenation of the in situ generated hemiacetal involving Au nanoparticles. 110 To date, several studies have been reported theoretical calculations to predict the reaction products and explain experimental activity through estimating the adsorption and dissociation energies of reactants over CeO 2 -based catalysts, the energy profiles of intermediates, the interaction of CeO 2 support with the supported active species, and so on, which is helpful for understanding the reaction mechanism.…”

Section: Reaction Mechanism Studiesmentioning

confidence: 99%

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Ceria-Based Materials for Thermocatalytic and Photocatalytic Organic Synthesis

et al. 2021

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Value-added chemicals, fuels, and pharmaceuticals synthesized by organic transformation from raw materials via catalytic techniques have attracted enormous attention in the past few decades. Heterogeneous catalysts with high stability, long cycling life, good environmental-friendliness, and economic efficiency are greatly desired to accomplish the catalytic organic transformations. With the advantages of reversible Ce3+/Ce4+ redox pairs, tailorable oxygen vacancies, and surface acid–base properties, ceria-based catalysts have been actively investigated in the fields of catalytic organic synthesis. In this Review, we summarize the fundamentals and latest applications of ceria-based heterogeneous catalysts for organic transformations via thermocatalytic and photocatalytic routes. The fabricating approaches of various ceria and ceria-based catalysts and their structure/composition–activity relationship are discussed and prospected. The advanced characterization techniques and theoretical methods for reaction mechanism studies over CeO2-based catalysts are summarized and discussed. This comprehensive Review provides a basic understanding of the structure–performance relationships of ceria-based catalysts for organic synthesis. In addition, it also provides some insights and outlooks in the design and research direction in the ceria-based catalysts with better performance.

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Section: Reaction Mechanism Studiesmentioning

confidence: 99%

Section: Reaction Mechanism Studiesmentioning

confidence: 99%

Ceria-Based Materials for Thermocatalytic and Photocatalytic Organic Synthesis

et al. 2021

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“…96% propyne conversion . This intriguing catalytic performance of ceria has stimulated considerable research efforts to understand the mechanism for the selective hydrogenation of alkyne by both experimental ,− and computational studies. − …”

Section: Introductionmentioning

confidence: 99%

Discriminating the Role of Surface Hydride and Hydroxyl for Acetylene Semihydrogenation over Ceria through In Situ Neutron and Infrared Spectroscopy

et al. 2020

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Ceria has been used as a hydrogenation catalyst especially in selective alkyne hydrogenation, but the reaction mechanism regarding the role of different surface hydrogen species remains unclear. In this work, we utilized in situ neutron and infrared vibration spectroscopy to show the catalytic role of cerium hydride (Ce–H) and hydroxyl (OH) groups in acetylene hydrogenation over ceria surfaces with different degree of reduction. In situ inelastic neutron scattering spectroscopy (INS) proved that not only Ce–H but also surface atomic hydrogen species on the reduced ceria surface can participate in acetylene semihydrogenation. In situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) results implied that bridging OH groups both on the oxidized and reduced ceria are active in the selective hydrogenation of acetylene. It appears that surface Ce–H is more reactive than the coexisting OH species on the reduced ceria surface, but over-reduction of ceria also results in strongly bound species that may lead to catalyst deactivation. These spectroscopic results clearly explain the reaction mechanism including not only the surface chemistry but also the nature of the active hydrogen species for selective hydrogenation over ceria, providing insights into the design of more active and stable ceria-based catalysts for hydrogenation reactions.

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“…31−33 Such SOMIs have been applied to a variety of oxide/metal inverse catalysts, such as ZnO/Au(111), 34 MgO/ Au(111), MgO/Ag(100), 14 TiO 2 /Au(111), 35 CeO 2 /Cu(111), 36 and CeO 2 /Ru(0001). 37 Among these, Au(111) has always been considered to be an ideal model for the growth of ultrathin FeO films due to its excellent reactivity and stability in the inverse catalysis process. 7,13 Because the atomic structures and properties of ultrathin oxide films are dramatically determined by the interfacial interactions, it is still essential to elucidate the growth mechanism and interface properties of the FeO/Au(111) system.…”

Section: Introductionmentioning

confidence: 99%

“…To date, many reports about the epitaxial growth mode and the SOMIs of iron oxide films on various metal substrates have been published, showing excellent catalytic activity in various reactions. , For instance, monolayer FeO on Pt(111) is highly active, selective, and robust for CO oxidation at room temperature (RT) because of SOMI, which provides an effective method for designing active sites of catalysts . Similar to the FeO(111)/Pt(111) system, FeO/Pd(111) can also promote hydrogenation/dehydrogenation reactions and CO oxidation. − Such SOMIs have been applied to a variety of oxide/metal inverse catalysts, such as ZnO/Au(111), MgO/Au(111), MgO/Ag(100), TiO 2 /Au(111), CeO 2 /Au(111), CeO 2 /Cu(111), and CeO 2 /Ru(0001) . Among these, Au(111) has always been considered to be an ideal model for the growth of ultrathin FeO films due to its excellent reactivity and stability in the inverse catalysis process. , Because the atomic structures and properties of ultrathin oxide films are dramatically determined by the interfacial interactions, it is still essential to elucidate the growth mechanism and interface properties of the FeO/Au(111) system. ,− Furthermore, a detailed understanding of the SOMI, how it affects the second layer metal oxide, needs to be extensively explored. , …”

Section: Introductionmentioning

confidence: 99%

Two-Dimensional Iron Oxide on Au(111): Growth Mechanism and Interfacial Properties

Jiang

Zhou

et al. 2021

J. Phys. Chem. C

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The strong oxide−metal interaction makes inverse oxide−metal configurations more active than conventional bulk systems. An atomic-scale understanding of the growth mechanism and structural properties of these metal oxides on noble metal substrates is essential for the design and improvement of inverse catalysts. Here, using two-dimensional iron oxide (FeO) thin films on the Au( 111) surface as a model system, we investigated the growth mechanism of the first and second layer FeO on Au(111) by highresolution scanning tunneling microscopy. Fe atoms embed in the subsurface of Au(111) at low coverage and squeeze out the surrounding Au atoms. Assisted by oxidation to generate FeO, the islands move to the surface and finally cover the Au(111) surface to form a Moirésuperstructure. Density functional theory calculations reveal the formation of the strong interfacial Fe−Au bonds and remarkable charge transfer. The second layer of FeO exhibits a modulated ellipsoidal Moirépattern because of the strong Fe−Fe bonds along with the variation of interlayer distance at different sites. This study on the growth mechanism and surface structures of mono-and bilayer FeO on Au(111) promotes future research on the metal oxide−substrate interactions in the field of catalysis.

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Water‐Assisted Homolytic Dissociation of Propyne on a Reduced Ceria Surface

Cited by 20 publications

References 49 publications

Ceria-Based Materials for Thermocatalytic and Photocatalytic Organic Synthesis

Ceria-Based Materials for Thermocatalytic and Photocatalytic Organic Synthesis

Discriminating the Role of Surface Hydride and Hydroxyl for Acetylene Semihydrogenation over Ceria through In Situ Neutron and Infrared Spectroscopy

Two-Dimensional Iron Oxide on Au(111): Growth Mechanism and Interfacial Properties

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