Role of σ,π-Digold(I) Alkyne Complexes in Reactions of Enynes

Ferrer, Sofia; Echavarren, Antonio M.

doi:10.1021/acs.organomet.7b00668

Cited by 36 publications

(28 citation statements)

References 78 publications

(93 reference statements)

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“…The use of tetraarylborate (BAr F ) as the anion was also found to be important to obtain consistently good yields . Kinetic experiments suggested that the deprotonation of terminal alkynes 132 is slower with this bulky anion, which minimizes the formation of undesired σ,π‐digold(I) alkyne complexes ,…”

Section: Development Of An Enantioselective Intermolecular [2+2] Cyclmentioning

confidence: 99%

“…[48b] Kinetic experiments suggested that the deprotonation of terminal alkynes 132 is slower with this bulky anion, which minimizes the formation of undesired s,p-digold(I) alkyne complexes. [50,51] The same gold(I) complex was used for the first intramolecular reaction of large enynes that leads to macrocycles by a [2 + 2] cycloaddition. [141] Thus, for example, 1,12-enyne 135 gave 11-membered ring macrocycle 136 a (Scheme 31).…”

Section: Development Of An Enantioselectivementioning

confidence: 99%

“…In the case of substrates bearing terminal alkynes, σ, π‐digold(I) alkyne complexes can also be formed, which are unproductive dead‐ends in catalytic reactions of enynes ,. However, the formation of these dinuclear gold(I) complexes is reversible, and in the presence of protic sources the free alkynes can be regenerated by protonolysis.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Gold(I)‐Catalysis for the Synthesis of Terpenoids: From Intramolecular Cascades to Intermolecular Cycloadditions

Mayans

Armengol-Relats

Calleja

et al. 2018

Israel Journal of Chemistry

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Gold(I)‐catalyzed cycloisomerizations of 1,n‐enynes proceed through electrophilic intermediates that can be trapped intra‐ or intermolecularly by a variety of hetero‐ and carbon nucleophiles to form complex skeletons in a single step. This review covers the efforts of our group towards the development of new reactions that have been successfully applied in the total synthesis of several natural terpenoids and related carbocyclic structures, as well as for the ready access to challenging linear acenes.

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Section: Development Of An Enantioselective Intermolecular [2+2] Cyclmentioning

confidence: 99%

Section: Development Of An Enantioselectivementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Gold(I)‐Catalysis for the Synthesis of Terpenoids: From Intramolecular Cascades to Intermolecular Cycloadditions

Mayans

Armengol-Relats

Calleja

et al. 2018

Israel Journal of Chemistry

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“…One year later, the Gasgosz's group studied a similar reactivity for the phosphinegold(I) catalyst highlighting its unusual dual character as nucleophile (C–H activation) and electrophile (alkyne activation) . These pioneering discoveries in cyclisation reactions with allenyne and dyines, which contain a C–C triple bond, enabled gold to form the so‐called σ,π‐digold‐acetylide complex , . This latter complex represented a landmark together with the introduction of N‐heterocyclic carbene (NHC) ligands by means of the stable gem‐diaurated [{Au(NHC)} 2 (µ‐OH)] species discovered by Nolan and co‐workers in 2013 .…”

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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“…Among others, silver salts are the most used agents for this purpose (Ranieri et al, 2015). Furthermore, both the electronic nature of ligands (Wang et al, 2012; Ebule et al, 2016; Gung et al, 2016; Ferrer and Echavarren, 2018a) and of the counterion (Homs et al, 2014; Ciancaleoni et al, 2015; Jia and Bandini, 2015; Rocchigiani et al, 2015; Gatto et al, 2016; Yuan et al, 2018; Schießl et al, 2018a,b) have a significant influence on the reactivity of the gold-catalyzed processes.…”

Section: Introductionmentioning

confidence: 99%

Gold-Catalyzed Homogeneous (Cyclo)Isomerization Reactions

2019

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Gold is currently one of the most used metals in organometallic catalysis. The ability of gold to activate unsaturated groups in different modes, together with its tolerance to a wide range of functional groups and reaction conditions, turns gold-based complexes into efficient and highly sought after catalysts. Natural products and relevant compounds with biological and pharmaceutical activity are often characterized by complex molecular structures. (Cyclo)isomerization reactions are often a useful strategy for the generation of this molecular complexity from synthetically accessible reactants. In this review, we collect the most recent contributions in which gold(I)- and/or gold(III)-catalysts mediate intramolecular (cyclo)isomerization transformations of unsaturated species, which commonly feature allene or alkyne motifs, and organize them depending on the substrate and the reaction type.

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Role of σ,π-Digold(I) Alkyne Complexes in Reactions of Enynes

Cited by 36 publications

References 78 publications

Gold(I)‐Catalysis for the Synthesis of Terpenoids: From Intramolecular Cascades to Intermolecular Cycloadditions

Gold(I)‐Catalysis for the Synthesis of Terpenoids: From Intramolecular Cascades to Intermolecular Cycloadditions

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

Gold-Catalyzed Homogeneous (Cyclo)Isomerization Reactions

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