Search results for "Palladium catalyst"

showing 10 items of 14 documents

Catalytic Carbonylative Double Cyclization of 2-(3-Hydroxy-1-yn-1-yl)phenols in Ionic Liquids Leading to Furobenzofuranone Derivatives

2019

A catalytic carbonylative double cyclization method for the synthesis of furo[3,4-b]benzofuran-1(3H)-ones is reported. It is based on the reaction between readily available 2-(3-hydroxy-1-yn-1-yl)phenols, CO, and oxygen carried out in the presence of catalytic amounts of PdI2 (1 mol %) in conjunction with KI (20 mol %) and 2 equiv of diisopropylethylamine at 80 degrees C for 24 h under 30 atm of a 1:4 mixture of CO-air. Interestingly, the process was not selective when carried out in classical organic non-nucleophilic solvents (such as MeCN or DME), leading to a mixture of the benzofurofuranone derivative and the benzofuran ensuing from simple cycloisomerization, whereas it turned out chemo…

010405 organic chemistryOrganic Chemistrychemistry.chemical_elementIonic LiquidsCarbonylationSettore CHIM/06 - Chimica Organica010402 general chemistry01 natural sciencesCarbonylation; Palladium; Cyclization; Ionic Liquids0104 chemical sciencesCatalysischemistry.chemical_compoundIonic liquids palladium catalyst benzofuranchemistryCyclizationIonic liquidOrganic chemistryPhenolsCarbonylationPalladiumPalladium
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3D Printed Palladium Catalyst for Suzuki-Miyaura Cross-coupling Reactions

2020

Selective laser sintering (SLS) 3d printing was utilized to manufacture a solid catalyst for Suzuki-Miyaura cross-coupling reactions from polypropylene as a base material and palladium nanoparticles on silica (SilicaCat Pd(0)R815-100 by SiliCycle) as the catalytically active additive. The 3d printed catalyst showed similar activity to that of the pristine powdery commercial catalyst, but with improved practical recoverability and reduced leaching of palladium into solution. Recycling of the printed catalyst led to increase of the induction period of the reactions, attributed to the pseudo-homogeneous catalysis. The reaction is initiated by oxidative addition of aryl iodide to palladium nano…

3d printedMaterials scienceNANOPARTICLE116 Chemical sciences3D printingNanoparticle010402 general chemistry01 natural sciencesCatalysisCoupling reactionlaw.inventionInorganic ChemistrykatalyytitlawMIZOROKI-HECK3D-tulostuspalladium nanoparticlesselective laser sinteringPhysical and Theoretical ChemistryFILTERSSuzuki-Miyaura cross-couplingcatalysis010405 organic chemistrybusiness.industry3d printingOrganic ChemistryPINCER COMPLEXESPalladium nanoparticlespalladium0104 chemical sciencesSelective laser sinteringChemical engineeringnanohiukkaset221 Nano-technologybusinessPalladium catalyst
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Palladium-catalyzed formation and reactions of iodo- and bromosiloxane intermediates

2012

Polysiloxanes are useful materials because of their functionality, such as high thermal stability, electrical resistance, and hydrophobicity. In this regard, we studied palladium-catalyzed formation of iodo-and bromopolysiloxanes from two types of hydrosiloxanes, alpha,omega-dihydropoly(dimethylsiloxane) (1) and cyclotetra(hydromethylsiloxane) (2), and their reactions. Treatment of 1 with mixtures of cyclic ethers or lactones and MeI or allylBr in the presence of a catalytic amount of PdCl2 gave the corresponding alpha,omega-bis(haloalkoxy and haloalkanoyloxy) poly(dimethylsiloxane)s in good yields, via iodo-and bromopoly(dimethylsiloxane) intermediates. Transformation of the iodobutoxy-ter…

BoromosilaneIodosilanechemistry.chemical_element430BiochemistryCatalysisInorganic Chemistrychemistry.chemical_compoundPolymer chemistryMaterials ChemistryThermal stabilityPhysical and Theoretical Chemistrychemistry.chemical_classification430Quenching (fluorescence)EthanolOrganic ChemistryPolysiloxanePolymerLactonechemistryCyclic etherPalladium catalystCyclic etherLactonePalladiumJournal of Organometallic Chemistry
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ChemInform Abstract: Switchable Palladium-Catalyst Reaction of Bromomethyl Sulfoxides, CO, and N-Nucleophiles: Aminocarbonylation at Csp3versus Oxida…

2013

Pd2(dba)3/ Xantphos-catalyzed coupling of the sulfoxides (I) and (V) with amines and carbon monoxide allows a new and efficient access to amides of type (IV) and (VI).

Coupling (electronics)chemistry.chemical_compoundNucleophileChemistryOxidative carbonylationPolymer chemistryGeneral MedicinePalladium catalystPyrrole derivativesCarbon monoxideChemInform
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Recyclable heterogeneous palladium catalysts in pure water: sustainable developments in Suzuki, Heck, Sonogashira and Tsuji-Trost reactions

2010

This review summarizes the progress made essentially these last ten years on heterogeneous palladium catalysis in pure water. The work covers four important palladium-catalyzed transformations for carbon-carbon bond formation: Suzuki, Heck, Sonogashira and Tsuji-Trost reactions. The discussion focuses on the efficiency and reusability of the heterogeneous catalysts as well as on the experimental conditions from a sustainable chemistry point of view. The review is introduced by a discussion on mechanistic aspects inherent to heterogeneous catalysis.

Green chemistryheterogeneous palladium catalysts010405 organic chemistrywaterSonogashira couplingchemistry.chemical_elementGeneral Chemistry[CHIM.CATA]Chemical Sciences/Catalysis010402 general chemistryHeterogeneous catalysis01 natural sciences7. Clean energySuzuki reaction -Tsuji-Trost reaction0104 chemical sciencesCatalysisTsuji–Trost reaction[ CHIM.CATA ] Chemical Sciences/CatalysisHeck reactionchemistrySuzuki reactionHeck reactionOrganic chemistrySonogashira reactionComputingMilieux_MISCELLANEOUSPalladium
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Accelerated dinuclear palladium catalyst identification through unsupervised machine learning.

2021

Although machine learning bears enormous potential to accelerate developments in homogeneous catalysis, the frequent need for extensive experimental data can be a bottleneck for implementation. Here, we report an unsupervised machine learning workflow that uses only five experimental data points. It makes use of generalized parameter databases that are complemented with problem-specific in silico data acquisition and clustering. We showcase the power of this strategy for the challenging problem of speciation of palladium (Pd) catalysts, for which a mechanistic rationale is currently lacking. From a total space of 348 ligands, the algorithm predicted, and we experimentally verified, a number…

Identification (information)MultidisciplinaryComputer sciencebusiness.industryUnsupervised learningHomogeneous catalysisArtificial intelligencebusinessMachine learningcomputer.software_genrecomputerPalladium catalystBottleneckScience (New York, N.Y.)
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A New Heterogeneous Catalyst Obtained via Supramolecular Decoration of Graphene with a Pd2+ Azamacrocyclic Complex

2019

A new G-(H2L)-Pd heterogeneous catalyst has been prepared via a self-assembly process consisting in the spontaneous adsorption, in water at room temperature, of a macrocyclic H2L ligand on graphene (G) (G + H2L = G-(H2L)), followed by decoration of the macrocycle with Pd2+ ions (G-(H2L) + Pd2+ = G-(H2L)-Pd) under the same mild conditions. This supramolecular approach is a sustainable (green) procedure that preserves the special characteristics of graphene and furnishes an efficient catalyst for the Cu-free Sonogashira cross coupling reaction between iodobenzene and phenylacetylene. Indeed, G-(H2L)-Pd shows an excellent conversion (90%) of reactants into diphenylacetylene under mild conditio…

Models MolecularChemical PhenomenaIodobenzeneMolecular ConformationPharmaceutical ScienceSonogashira couplingLigands010402 general chemistryHeterogeneous catalysiscross coupling01 natural sciencesArticleCoupling reactionAnalytical Chemistrylaw.inventionCatalysislcsh:QD241-441chemistry.chemical_compoundlcsh:Organic chemistryCoordination ComplexeslawDrug DiscoveryPolymer chemistryPhysical and Theoretical ChemistryDiphenylacetyleneMolecular Structurecatalysis010405 organic chemistryGrapheneSpectrum AnalysisOrganic ChemistrySonogashirapalladium catalystHydrogen-Ion Concentrationsupramolecular interactions0104 chemical sciencesSolutionsazamacrocycleschemistryPhenylacetyleneChemistry (miscellaneous)surface adsorptionMolecular MedicineGraphitecatalysis palladium catalyst; Sonogashira graphenePalladiumMolecules
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α-d-Glucopyranose Adsorption on a Pd30 Cluster Supported on Boron Nitride Nanotube

2016

Boron nitride nanotube (BNNT) as an innovative support for carbohydrate transformation processes was evaluated, using density functional theory. The α-d-glucopyranose adsorption on a Pd30 cluster, supported on BNNT, was used to check both the local activity of topologically different metallic sites and the effects of the proximity of the BNNT surface to the same metallic sites. Detailed geometrical and electronic analyses performed on Pd30/BNNT and α-d-glucopyranose/Pd30/BNNT systems were discussed. It was observed that the deposition of the Pd30 cluster onto the BNNT support gives rise to an electronic rearrangement, determining a charge transfer from the support to the adsorbed metal clus…

Surface site reactivityChemical substanceNanotechnologyElectron donor02 engineering and technology010402 general chemistryDFT01 natural sciencesBoron nitride nanotubeCatalysisCatalysiCatalysisMetalchemistry.chemical_compoundAdsorptionSupported palladium catalystCluster (physics)Chemistry (all)Molecular electrostatic potentialGeneral Chemistry021001 nanoscience & nanotechnologyBoron nitride nanotube; DFT; Molecular electrostatic potential; Supported palladium catalyst; Surface site reactivity; α-d-Glucopyranose adsorption; Catalysis; Chemistry (all)0104 chemical scienceschemistryChemical physicsvisual_artα-d-Glucopyranose adsorptionvisual_art.visual_art_mediumDensity functional theory0210 nano-technologyScience technology and societyTopics in Catalysis
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AC3-Symmetric Palladium Catalyst with a Phosphorus-Based Tripodal Ligand

2006

chemistryPhosphorusTripodal ligandInorganic chemistrychemistry.chemical_elementGeneral MedicineGeneral ChemistryPalladium catalystCatalysisPalladiumAngewandte Chemie International Edition
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ChemInform Abstract: Sequential Suzuki/Asymmetric Aldol and Suzuki/Knoevenagel Reactions under Aqueous Conditions.

2012

Here we describe for the first time a sequential Suzuki/asymmetric aldol reaction. Such sequential approach was achieved through the combined use of an ionic liquid supported palladium catalyst and the organocatalyst trans-4-(2,2-diphenylacetoxy)proline. Suzuki and asymmetric aldol reactions were performed under aqueous conditions. The use of a palladium catalyst under basic conditions allowed also the first example of sequential Suzuki/Knoevenagel reaction. Reactions were carried out under aqueous conditions and products were isolated in good to high yields and, in the case of the Suzuki/aldol reaction, with diastereoselectivities up to 91:9 and enantioselectivities up to at least 99 %.

chemistry.chemical_compoundAddition reactionAqueous solutionchemistryAldol reactionCombined useIonic liquidOrganic chemistryKnoevenagel condensationGeneral MedicinePalladium catalystChemInform
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