Supported Metal Nanoparticles Assisted Catalysis: A Broad Concept in Functionalization of Ubiquitous C−H Bonds

Baroliya, Prabhat Kumar; Chopra, Jaishri; Pal, Tanay; Maiti, Sukumar; Al‐Thabaiti, Shaeel Ahmed; Mokhtar, Mohamed

doi:10.1002/cctc.202100755

Cited by 17 publications

(7 citation statements)

References 176 publications

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“…In the past few decades, the development of C-H functionalization reactions that enable the construction of fundamentally important C-C and C-X bonds has witnessed tremendous upsurge. [1][2][3][4][5][6][7][8][9][10][11] Within the domain, transition metal catalysis forms the largest, ever expanding subset contributing to the broad spectrum of applications that ranges from organic synthesis to petrochemical processing. [12][13][14][15][16][17][18][19][20] In this context, the development of novel methods to access arylation, [21][22][23][24] alkenylation [25][26][27] and alkynylation of C-H bonds 28 has gained tremendous attention.…”

Section: Introductionmentioning

confidence: 99%

Transition-metal-catalyzed C–H bond alkylation using olefins: recent advances and mechanistic aspects

et al. 2022

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Section: Introductionmentioning

confidence: 99%

Transition-metal-catalyzed C–H bond alkylation using olefins: recent advances and mechanistic aspects

et al. 2022

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“…Noble metal nanostructures exhibit fascinating catalytic properties for a wide range of reactions important in the chemical and pharmaceutical industries, but the downside is that during the synthesis or under catalytic operating conditions, sintering or coalescence invariably deteriorates the quality of metal nanoparticles (NPs) because of the thermodynamically unstable nature. − Deposition of noble metal catalysts onto metal oxide supports has been proven to be one of the most effective strategies to stabilize the NPs. Supported NPs display improved activities compared to their nonsupported counterparts due to the synergetic effects originated at the metal–metal oxide heterojunction via altered electronic structures. − A range of precious metal catalysts have been so far loaded on different transition or nontransition metals oxides with the purpose of improving stability and attaining enhanced activity. − The incipient impregnation, chemical vapor deposition, laser ablation, and electrochemical deposition approaches have been adopted for deposition of metal NPs. − Alternatively, high-quality monodispersed metal NPs with a narrow particle size distribution are synthesized under the protection of stabilizers (i.e., polymer or surfactant) prior to loading on supports, but the presence of the stabilizers at the interface between the metal NPs and the support minimizes the direct contact or electronic communication between metals and supports. − Naked NPs with maximum active surface areas are mostly the desired product; there have been few reports where bare metal NPs were in situ grown outside or inside metal oxides structures. − For instance, MnO nanocrystals were used as a reactive template to electrolessly deposit platinum NPs onto the surface via the galvanic replacement reaction. , In other reports, noble metal NPs were deposited on WO 2 nanowires and TiO 2 NPs. − There have been reports wherein metal core cerium oxide shelled based nanostructures were produced using wet chemical reaction systems. − In this study, we report as-synthesized hollow CeO 2 nanospheres as an electron reservoir to reduce the metal salts into metal NPs under optimized synthetic conditions, in contrast to previous reports wherein CeO 2 shells were formed on metal NPs. In this study, metal N...…”

Section: Introductionmentioning

confidence: 99%

Nanoceria as an Electron Reservoir: Spontaneous Deposition of Metal Nanoparticles on Oxides and Their Anti-inflammatory Activities

et al. 2022

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Designing metal−metal oxide heteronanostructures with synergistic and superior activities (unattainable in the case of a single entity) is of great interest for a wide range of technological applications. Traditional synthetic strategies typically require reducing agents, stabilizing ligands, or high temperature reductive treatment to produce oxide-supported metals. Herein, a facile noble metal deposition strategy is developed to produce silver, gold, and platinum nanocrystals on the surface of hollow mesoporous cerium oxide nanospheres without any pretreatment. Unlike the galvanic replacement reaction, the developed protocol employs the innate reductive potential of CeO 2 to produce a high density of ultrafine noble metal nanocrystals homogeneously immobilized onto the surface of CeO 2 nanospheres. The multienzyme-like activities (i.e., superoxide dismutase-like and catalase-like) of CeO 2 @ metal nanostructures, originating from CeO 2 and metal nanoparticles, were effectively utilized for anti-inflammatory therapies in two in vivo models. This oxygen vacancy-mediated reduction strategy can be generalized to produce diverse metal−metal oxide nanostructures for a wide range of applications.

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“… 15 − 19 Thus, supported metal nanoparticle catalysts have the potential to create novel active site structures for efficient C–H bond activation via unique mechanisms. 20 However, the reaction mechanism with supported metal nanoparticle catalysts and the structure of the catalytically active sites are not well understood at the elementary reaction level, which makes developing general heterogeneous catalyst design strategies extremely difficult.…”

Section: Introductionmentioning

confidence: 99%

“…Supported metal nanoparticle catalysts are easy to separate and reuse, which is an attractive feature for green chemistry. In addition, supported metal nanoparticle catalysts can create unique active site structures different from those of homogeneous complex catalysts and sometimes outperform homogeneous catalysts by utilizing their specific systems, such as the ensemble effect, ligand effect, concerted catalysis, and geometric structures (e.g., core–shell, cluster-in-cluster, and alloy structures). − Thus, supported metal nanoparticle catalysts have the potential to create novel active site structures for efficient C–H bond activation via unique mechanisms . However, the reaction mechanism with supported metal nanoparticle catalysts and the structure of the catalytically active sites are not well understood at the elementary reaction level, which makes developing general heterogeneous catalyst design strategies extremely difficult.…”

Section: Introductionmentioning

confidence: 99%

C–H Bond Activation Mechanism by a Pd(II)–(μ-O)–Au(0) Structure Unique to Heterogeneous Catalysts

Takei

Yatabe

Yabe

et al. 2022

JACS Au

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We focused on identifying a catalytic active site structure at the atomic level and elucidating the mechanism at the elementary reaction level of liquid-phase organic reactions with a heterogeneous catalyst. In this study, we experimentally and computationally investigated efficient C–H bond activation for the selective aerobic α,β-dehydrogenation of saturated ketones by using a Pd–Au bimetallic nanoparticle catalyst supported on CeO 2 (Pd/Au/CeO 2 ) as a case study. Detailed characterization of the catalyst with various observation methods revealed that bimetallic nanoparticles formed on the CeO 2 support with an average size of about 2.5 nm and comprised a Au nanoparticle core and PdO nanospecies dispersed on the core. The formation mechanism of the nanoparticles was clarified through using several CeO 2 -supported controlled catalysts. Activity tests and detailed characterizations demonstrated that the dehydrogenation activity increased with the coordination numbers of Pd–O species in the presence of Au(0) species. Such experimental evidence suggests that a Pd(II)–(μ-O)–Au(0) structure is the true active site for this reaction. Based on density functional theory calculations using a suitable Pd 1 O 2 Au 12 cluster model with the Pd(II)–(μ-O)–Au(0) structure, we propose a C–H bond activation mechanism via concerted catalysis in which the Pd atom acts as a Lewis acid and the adjacent μ-oxo species acts as a Brønsted base simultaneously. The calculated results reproduced the experimental results for the selective formation of 2-cyclohexen-1-one from cyclohexanone without forming phenol, the regioselectivity of the reaction, the turnover-limiting step, and the activation energy.

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Supported Metal Nanoparticles Assisted Catalysis: A Broad Concept in Functionalization of Ubiquitous C−H Bonds

Cited by 17 publications

References 176 publications

Transition-metal-catalyzed C–H bond alkylation using olefins: recent advances and mechanistic aspects

Transition-metal-catalyzed C–H bond alkylation using olefins: recent advances and mechanistic aspects

Nanoceria as an Electron Reservoir: Spontaneous Deposition of Metal Nanoparticles on Oxides and Their Anti-inflammatory Activities

C–H Bond Activation Mechanism by a Pd(II)–(μ-O)–Au(0) Structure Unique to Heterogeneous Catalysts

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