The [3 + 3]-Cycloaddition Alternative for Heterocycle Syntheses: Catalytically Generated Metalloenolcarbenes as Dipolar Adducts

Abstract: ConspectusThe combination of two or more unsaturated structural units to form cyclic organic compounds is commonly referred to as cycloaddition, and the combination of two unsaturated structural units that forms a six-membered ring is formally either a [5 + 1]-, [4 + 2]-, [2 + 2 + 2]-, or [3 + 3]-cycloaddition. Occurring as concerted or stepwise processes, cycloaddition reactions are among the most useful synthetic constructions in organic chemistry. Of these transformations, the concerted [4 + 2]-cycloadditio… Show more

“…[5] The reactivity of bimetallic iridium complexes with substrates such as alkynes, molecular hydrogen, halogens, or halocarbons very often diverges from that of their mononuclear analogues. [6] In the particular case of bimetallic Ir(II) complexes the activation of the substrate may occur by single-site oxidative addition at one of the metal centres.…”

“…[4] The lack of examples of iridium(II) catalysts sharply contrasts with the widespread application of rhodium(II) complexes in catalysis, especially remarkable are the dinuclear catalysts reported by Doyle and coworkers. [5] The reactivity of bimetallic iridium complexes with substrates such as alkynes, molecular hydrogen, halogens, or halocarbons very often diverges from that of their mononuclear analogues. [6] In the particular case of bimetallic Ir(II) complexes the activation of the substrate may occur by single-site oxidative addition at one of the metal centres.…”

A bimetallic iridium(ii) catalyst: [{Ir(IDipp)(H)}₂][BF₄]₂ (IDipp = 1,3-bis(2,6-diisopropylphenylimidazol-2-ylidene))

“…[5] The reactivity of bimetallic iridium complexes with substrates such as alkynes, molecular hydrogen, halogens, or halocarbons very often diverges from that of their mononuclear analogues. [6] In the particular case of bimetallic Ir(II) complexes the activation of the substrate may occur by single-site oxidative addition at one of the metal centres.…”

“…[4] The lack of examples of iridium(II) catalysts sharply contrasts with the widespread application of rhodium(II) complexes in catalysis, especially remarkable are the dinuclear catalysts reported by Doyle and coworkers. [5] The reactivity of bimetallic iridium complexes with substrates such as alkynes, molecular hydrogen, halogens, or halocarbons very often diverges from that of their mononuclear analogues. [6] In the particular case of bimetallic Ir(II) complexes the activation of the substrate may occur by single-site oxidative addition at one of the metal centres.…”

A bimetallic iridium(ii) catalyst: [{Ir(IDipp)(H)}₂][BF₄]₂ (IDipp = 1,3-bis(2,6-diisopropylphenylimidazol-2-ylidene))

“…Many articles focusing on some aspect of carbene complex-initiated olefin metathesis were published, including the following specific subjects: (1) the evolution of catalytic stereoselective olefin metathesis [28]; (2) development of cleaner olefin metathesis catalysts [29]; (3) key processes in ruthenium catalyzed olefin metathesis [30]; (4) olefin metathesis in the preparation of active pharmaceutical substances [31]; (5) industrially relevant olefin metathesis catalysts [32]; (6) olefin metathesis in the synthesis of natural products [33]; (7) multi-reaction processes involving Overman rearrangements, metathesis cyclizations, and Diels-Alder reactions [34]; (8) metathesis and polymerization [35]; (9) ROMP of eight-membered ring cyclic olefins [36];…”

“…7, syn isomers were more active; Hoveyda-Grubbs catalysts analogs were also prepared) [163]; (2) indenylidene ligands in place of the benzylidene group and unsymmetrical NHC ligands [164]; (3) a chelating pyridyl alkoxide ligands in place of the phosphine and one chloride ligand [165];…”

“…Tungsten catalysts of general structure 40 were highly effective in promoting Z-selective and stereoregular polymerization of norbornadiene diester derivative 39 [242]. Severally computationally-based studies of olefin metathesis were reported in 2014, including publications that focus on the following topics: (1) the feasibility of iron olefin metathesis catalysts (the pathway involving the iron analog of catalyst 2 is slightly less endothermic than ruthenium catalyst 2) [275,276]; (2) a comparison of various computational techniques (comparison of time and accuracy) for the complete ruthenium-catalyzed olefin metathesis pathway [277]; (3) orbital symmetry in the [2+2] cycloaddition step of olefin metathesis [278]; (4) the electronic effect of various alkylidene groups on the carbon-metal double bond strength (=CH 2 vs =CHF vs =CF 2 ), plus a comparison of Group 8 metals and similar studies on ruthenium metallacyclobutanes using coupled cluster theory [279]; (5) the cross metathesis of propene and styrene focused on the energies and interconversions of metallacyclobutane intermediates [280]; (6) 1-octene self metathesis [281,282]; (7) the ring opening of 3,3-dimethylcyclopropane using W(NH)(CH 2 )(OMe) 2 [283]; (8) olefin metathesis focusing on cis/trans olefin substrate coordination issues [284]; (9) microwave assisted RCM…”

The chemistry of the carbon-transition metal double and triple bond: Annual survey covering the year 2014

Addition Reactions: Cycloaddition