Catalytic Reactions on Model Gold Surfaces: Effect of Surface Steps and of Surface Doping

Fajín, José L. C.; Natália, M.; Cordeiro, Diana; Gomes, José R. B.

doi:10.3390/catal1010040

Cited by 8 publications

(3 citation statements)

References 62 publications

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“…Secondly, Au-Pd/MC offered abundant acid sites, which might favor the contact between the catalyst and C-OH bond in the intermediates, thereby improving the yield of ketones. Thirdly, the Au nanocatalyst was known to have high O 2 activation ability and be effective in oxidizing various organic compounds with O 2 as the oxidant [49]. The introduction of Pd species would favor the O 2 activation to generate active oxygen species, leading to enhanced catalytic activity [30].…”

Section: Reaction Pathwaymentioning

confidence: 99%

Boosting Solvent-Free Aerobic Oxidation of Benzylic Compounds into Ketones over Au-Pd Nanoparticles Supported by Porous Carbon

Sun,

Peng,

Guo

et al. 2024

Catalysts

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The exploitation of highly efficient solvent-free catalytic systems for the selective aerobic oxidation of benzylic compounds to produce corresponding ketones with molecular oxygen under mild conditions remains a great challenge in the chemical industry. In this work, Au-Pd nanoparticles supported on porous carbon catalysts were fabricated by the borax-mediated hydrothermal carbonization method and the chemical reduction method. The physicochemical properties of Au-Pd bimetallic samples were examined by XRD, N2 sorption, SEM, TEM, and XPS techniques. The Au-Pd nanoparticles have successfully immobilized on the spherical carbon support with a porous structure and large surface area. A solvent-free catalytic oxidation system was constructed to selectively convert indane into indanone with Au-Pd nanocatalysts and O2. In contrast with a monometallic Au or Pd catalyst, the resulting bimetallic Au-Pd catalyst could effectively activate O2 and exhibit improved catalytic activity in the controlled oxidation of indane into indanone under 1 bar O2. A total of 78% conversion and >99% selectivity toward indanone can be achieved under optimized conditions. The synergistic effect of Au and Pd and porous carbon support contributed to the high catalytic activity for aerobic benzylic compound oxidation. This work offers a promising application prospect of efficient and recyclable Au-Pd nanocatalysts in functional benzylic ketone production.

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Section: Reaction Pathwaymentioning

confidence: 99%

Boosting Solvent-Free Aerobic Oxidation of Benzylic Compounds into Ketones over Au-Pd Nanoparticles Supported by Porous Carbon

Sun,

Peng,

Guo

et al. 2024

Catalysts

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“…The first review article by Sun et al [1] covers aspects of atomically monodisperse gold nanoclusters, with precise core-shell structure, which are fundamental to design new types of highly active and selective gold catalysts for a variety of catalytic processes. The role of surface steps and surface doping in the catalytic reactions on model gold surface was addressed through Density Functional Theory (DFT) based calculations by Gomes and coworkers [2] in a second review. Recent developments on synthesis of gold catalysts supported on mesoporous silica were exhaustively reviewed by Belkacemi et al [3] who highlighted the importance of gold nanoparticles incorporation into the channels in order to prevent Au agglomeration and leaching.…”

Section: The Present Issuementioning

confidence: 99%

New Frontiers in Gold Catalyzed Reactions

Liotta

2012

Catalysts

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BackgroundFor many years, gold has been regarded as a poor catalyst due to its chemical inertness towards reactive molecules such as oxygen and hydrogen. The interest in using gold in catalysis has increased during the last 20 years, since Haruta reported the surprisingly high activity in CO oxidation at low temperature for small (3-5 nm) gold particles supported on various oxides.Since then, gold nanostructured catalysts have attracted, rapidly growing attention, due to their potential applicability in various reactions of industrial and environment interest. The catalytic applications of gold have been, indeed, explored in several processes, such as NO removal, catalytic combustion of Volatile Organic Compound (VOC), hydrotreatment and chemical processing, and purification of hydrogen for fuel cell applications. Moreover, gold catalysts are, nowadays, employed as air-cleaning devices, for respiratory protection (gas masks), as sensors to detect individual poisonous or flammable gases, as well as deodorizers. Gold catalysts with low-temperature activity towards CO and hydrocarbons oxidation are suitable also for vehicles exhaust gas treatment, especially during the cold start period. Accordingly, at the end of 2007 the company Nanostellar announced the development of a diesel exhaust catalyst using a first catalytic component based on gold alloyed with palladium as the active component for CO oxidation. Nevertheless, despite the extensive recent efforts addressing the extraordinary catalytic behavior of gold nanoparticles, the attainment of the best performing supported gold catalyst is still a challenge and the origin of the structure sensitivity of Au catalytic activity is yet to be completely unravelled. The main reason for this is ascribed to the multiplicity of factors influencing the catalytic activity, including the size of the Au clusters, the oxidation state of gold, the nature of the support material, the Au-support interface, and the preparation method. The catalytic performances of gold nanoparticles have been correlated, in turn, with electronic (quantum size effect, oxidation state), structural and support (defects, perimeter interface) effects, but a OPEN ACCESS

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“…The release of pollutants from industries and other resources have increased the environmental problems. , The most noticeable contaminants are nitrogen oxides (NO, NO 2 , and N 2 O) which are mostly generated from combustion of fuel that contributes to the photochemical smog, acid rain formation, depletion of the ozone, and greenhouse effects. , Mostly, fuel combustion contains 95% NO and 5% NO 2 . NO is a hazardous gas which has an adverse effect on atmosphere, human respiratory system, and ecosystem. , Therefore, it is substantial to enterprise catalytic techniques to reduce or remove NO molecules from the atmosphere. − In recent years, it is proved computationally and experimentally that the single metal atoms effectively anchored and stabilized on a suitable metal oxide surface or another metal supports for catalysis. Recently, Allard et al reported through theoretical modeling that the Pd single atom supported on the θ-Al 2 O 3 surface shows excellent catalytic performance for NO oxidation .…”

Section: Introductionmentioning

confidence: 99%

Chromium Single-Atom Catalyst with Graphyne Support: A Theoretical Study of NO Oxidation and Reduction

et al. 2020

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Catalytic mechanisms and bonding analysis of NO oxidation and reduction on Cr single-atom catalysts (SAC) dispersed on the graphyne (GY) surface have been systematically investigated using the first-principles theoretical methods. GY is a decent support for isolated transition-metal (TM) atom catalysts because the most active sp-hybridized carbon atoms exist on the GY surface. All the single TM atoms are trapped into the void of the GY surface and existed in the isolated form. The molecular geometries and adsorbate binding energies of NO@TM–GY, ON@TM–GY, and O2@TM–GY configurations are determined. We find that the Cr–GY is the most promising SAC for NO oxidation and reduction compared with the other TM-SACs. Herein, we report an efficient NO oxidation and reduction catalyzed by Cr–GY at ambient temperature. We find that Cr–GY SAC is very reactive for NO oxidation and reduction at ambient temperatures with low activation barriers to the rate-determining steps for Eley–Rideal (0.87, 0.60, and 0.62 eV) and Langmuir–Hinshelwood (0.69, 0.62, and 0.84 eV) mechanisms. The Termolecular Eley–Rideal mechanism for the formation of the NO2 molecule is not thermodynamically favorable. Comparative analysis revealed that the NO reduction (0.62 eV) is more favorable than NO oxidation (0.84 eV). These findings provide valuable perceptions for design of highly efficient and selective heterogeneous SACs for NO oxidation and reduction with TMs.

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Catalytic Reactions on Model Gold Surfaces: Effect of Surface Steps and of Surface Doping

Cited by 8 publications

References 62 publications

Boosting Solvent-Free Aerobic Oxidation of Benzylic Compounds into Ketones over Au-Pd Nanoparticles Supported by Porous Carbon

Boosting Solvent-Free Aerobic Oxidation of Benzylic Compounds into Ketones over Au-Pd Nanoparticles Supported by Porous Carbon

New Frontiers in Gold Catalyzed Reactions

Chromium Single-Atom Catalyst with Graphyne Support: A Theoretical Study of NO Oxidation and Reduction

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