The preference for dual-gold(<scp>i</scp>) catalysis in the hydro(alkoxylation vs. phenoxylation) of alkynes

Casals-Cruañas, Èric; González-Belman, Oscar F.; Besalú-Sala, Pau; Nelson, David J.; Poater, Albert

doi:10.1039/c7ob01457k

Cited by 18 publications

(18 citation statements)

References 97 publications

(100 reference statements)

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“…[69,70,[79][80][81][82][71][72][73][74][75][76][77][78] In the majority of homogeneous Au catalysts, Au exists in the + 1 oxidation state. [103][104][105][106][107] In the past, the applications of Au I in enantioselectiver eactions have been considered challenging. The relativistic effects cause the contraction of 6s and 6p orbitals andt he expansion of 5d orbitals in Au I .…”

Section: Introductionmentioning

confidence: 99%

Gold‐Catalyzed Cross‐Coupling Reactions: An Overview of Design Strategies, Mechanistic Studies, and Applications

Nijamudheen

Datta

2019

Chemistry A European J

135

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Transition-metal-catalyzed cross-couplingr eactions are central to many organic synthesis methodologies. Traditionally,P d, Ni, Cu, and Fe catalysts are used to promote these reactions. Recently,m any studies have showedt hat both homogeneous and heterogeneous Au catalysts can be used for activating selective cross-coupling reactions.H ere, an overview of the past studies, current trends, andf uture directions in the field of gold-catalyzed coupling reactions is presented.D esign strategiest oa ccomplish selective homocoupling and cross-coupling reactions under both homogeneous and heterogeneous conditions, computational and ex-perimental mechanistic studies, and their applicationsi nd iverse fields are critically reviewed. Specific topics covered are:o xidant-assisted and oxidant-free reactions;s train-assisted reactions;d ual Au and photoredoxc atalysis;b imetallic synergistic reactions;m echanismso fr eductivee limination processes;e nzyme-mimicking Au chemistry;c lustera nd surface reactions;a nd plasmonic catalysis. In the relevant sections, theoretical and computational studies of Au I /Au III chemistry are discussed and the predictionsf rom the calculationsa re compared with the experimental observations to derive useful design strategies.A. Nijamudheen earnedh is PhD from IACS, Kolkata,i n2 015. Currently,h ei sapostdoctoral researcher atF loridaS tate University.H is researchi nterests are in computational catalysis, solar energym aterials, and beyond Li-ion battery technologies.Ayan Dattai sc urrently aP rofessor at IACS, Kolkata.H is research interests include theoretical and computational studieso ft ransitionmetal-catalyzed reactions,o pto-electronic properties of organic and solid-statem aterials, and the design of renewableenergymaterials. He has won several awards including the DST-SERB Distinguished Investigator Award (DIA) in 2019.

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Section: Introductionmentioning

confidence: 99%

Gold‐Catalyzed Cross‐Coupling Reactions: An Overview of Design Strategies, Mechanistic Studies, and Applications

Nijamudheen

Datta

2019

Chemistry A European J

135

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“…In this frame, a case that partially deviates from this general trend, is represented by the hydrophenoxylation of diphenylacetylene catalyzed by the dinuclear gold(I) complex [{Au(IPr)} 2 (µ-OH)][BF 4 ], studied in detail by Nolan and coworkers [14][15][16]. In this reaction, the gold catalyst is not only involved in the alkyne activation by forming the A-type π-complex (Scheme 1), but also reacts at the first stage of the reaction with phenol, forming the species [{Au(IPr)} 2 (µ-OPh)] + , thus also activating the nucleophile [15].…”

Section: Introductionmentioning

confidence: 99%

Hydroalkoxylation of Terminal and Internal Alkynes Catalyzed by Dinuclear Gold(I) Complexes with Bridging Di(N-Heterocyclic Carbene) Ligands

et al. 2019

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A series of six dinuclear gold(I) complexes with bridging bidentate N-heterocycic carbene ligands (NHCs) of general formula Au2Br2LX (L = diNHC, X = 1–6) have been studied as catalysts in the intermolecular hydroalkoxylation of terminal and internal alkynes. The best catalytic results have been obtained by using Au2Br2L4, characterized by 2,6-diisopropylphenyl wingtip substituents and a methylene bridging group between the two NHC donors. Complex Au2Br2L4 has been structurally characterized for the first time in this work, showing the presence of intramolecular aurophiclic interaction in the solid state. In the adopted reaction conditions Au2Br2L4 is able to convert challenging substrates such as diphenylacetylene. Comparative catalytic tests by using the mononuclear gold(I) complexes AuIL7 and IPrAuCl have been performed in order to determine the possible presence of cooperative effects in the catalytic process.

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“…For the sake of consistency, single point energy calculations on the Gaussian09 optimised structures have been undertaken for the ADF calculations. Part of the geometry optimisations is extracted from past work of Poater and co‐workers , …”

Section: Computational Detailsmentioning

confidence: 99%

“…Note that [Au] = Au(IMe). [23] Heterobimetallic complexes have been also matter of study due to the fact that the bifunctionality of different metals can lead to unique reactivity. Recent work by Cazin et al reported the hydrophenoxylation of internal alkynes with heterobimetallic Cu-NHC/Au-NHC systems, [35] in line with previous works on two metal moieties bearing different metal nature.…”

Section: Introductionmentioning

confidence: 99%

Phenoxylation of Alkynes through Mono‐ and Dual Activation Using Group 11 (Cu, Ag, Au) Catalysts

et al. 2020

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NHC‐gold(I) based catalysts have displayed outstanding results toward hydroalkoxylation of terminal and internal alkynes in solvent‐free conditions and using low catalyst loadings. It has been demonstrated that, in the hydrophenoxylation reaction the gold complex is composed by two moieties that determine the rate of the reaction by activating both substrates synergistically, i.e. [Au(OR)(NHC)] and [Au(η2‐alkyne)(NHC)]+. Then, these bimetallic systems act cooperatively toward the hydroalkoxylation reaction. Herein, density functional theory studies were carried out to get insights on the mechanism of hydrophenoxylation. The rate‐determining step, which corresponds to the formation of the C(alkyne)–O(alcohol) bond between [Au(OR)(NHC)] and [Au(η2‐alkyne)(NHC)]+, was studied using energy decomposition analyses (EDA). It was found that the C–O bond shows strong electrostatic and orbital interactions between both fragments in the homobimetallic, heterobimetallic and monogold mechanisms. Moreover, the analyses were expanded to copper and argentum, and the steric sensibility was also studied through the use of different NHC ligands, including IMes, IMe, SIMes, IPr, and IPr*, that differ on their steric demand.

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The preference for dual-gold(i) catalysis in the hydro(alkoxylation vs. phenoxylation) of alkynes

Cited by 18 publications

References 97 publications

Gold‐Catalyzed Cross‐Coupling Reactions: An Overview of Design Strategies, Mechanistic Studies, and Applications

Gold‐Catalyzed Cross‐Coupling Reactions: An Overview of Design Strategies, Mechanistic Studies, and Applications

Hydroalkoxylation of Terminal and Internal Alkynes Catalyzed by Dinuclear Gold(I) Complexes with Bridging Di(N-Heterocyclic Carbene) Ligands

Phenoxylation of Alkynes through Mono‐ and Dual Activation Using Group 11 (Cu, Ag, Au) Catalysts

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