Pauson-Khand reaction dicobalt octacarbonyl

A combination of Co-mediated amino-carbonylation and a Pauson-Khand reaction was described by Pericas and colleagues [286], with the formation of five new bonds in a single operation. Reaction of l-chloro-2-phenylacetylene 6/4-34 and dicobalt octacarbonyl gave the two cobalt complexes 6/4-36 and 6/4-37 via 6/4-35, which were treated with an amine 6/4-38. The final products of this domino process are azadi- and azatriquinanes 6/4-40 with 6/4-39 as an intermediate, which can also be isolated and separately transformed into 6/4-40 (Scheme 6/4.11). 

The [2+2+1] cycloaddition of an alkene, an alkyne, and carbon monoxide is known as the Pauson-Khand reaction and is often the method of choice for the preparation of complex cyclopentenones [155]. Groth and coworkers have demonstrated that Pauson-Khand reactions can be carried out very efficiently under microwave heating conditions (Scheme 6.75 a) [156]. Taking advantage of sealed-vessel technology, 20 mol% of dicobalt octacarbonyl was found to be sufficient to drive all of the studied Pauson-Khand reactions to completion, without the need for additional carbon monoxide. The carefully optimized reaction conditions utilized 1.2 equivalents of... 

Ethynylcyclopropanes, like normal acetylenes, react with dicobalt octacarbonyl in ether to form stable dinuclear cluster-like hexacarbonyl complexes (equation 170)236. The complex with l-chIoro-2,2,3,3-tetramethylethynylcyclopropane reacts stereo- and regioselec-tively with norbomene in a typical Pauson-Khand reaction to give the exn-2-cyclopropyl substituted cyclopentenone (equation 171). Similarly, the reaction of 2-ethoxycyclo-propylacetylene with cyclopentene in the presence of Co2(CO)8 under CO gave 3-(2-ethoxycyclopropyl)-cw-bicyclo[3.3.0]oct-3-en-2-one (equation 172)242. 

Amine—bis(amide) ligands, in chromium(III) models, 5, 376 Amine 7V-oxide promoters, in Pauson—Khand reaction with dicobalt octacarbonyl, 11, 337 Amines... 

Dicobalt octacarbonyl, in Pauson—Khand reaction homogeneous catalysis, 11, 340 metal-coupled promoters, 11, 339 non-oxidative promoter-assisted, 11, 338 oxidative promoter-assisted, 11, 337 physical promoters, 11, 339 solid-supported promoters, 11, 339 Dicobalt triple-decker sandwiches, preparation, 3, 14 (+)-Dictamnol, via [5+2]-cycloadditions, 10, 613-614 Dicyclohexylborane, for alkene hydroboration, 9, 150... 

Oxidative alkoxycarbonylation asymmetric carbonylation, 11, 467 catalyst development, 11, 467 mechanism, 11, 466 Oxidative amination, olefins, 10, 155 Oxidative cleavage, mechanisms, 1, 103 Oxidative promoters, in Pauson-Khand reaction with dicobalt octacarbonyl, 11, 337... 

A further addition-cyclization process that leads to complex fused-ring systems is the dicobalt octacarbonyl-mediated Pauson-Khand reaction which, applied to enynes 209 and 211, gives respectively and in modest yields the tricyclic cyclopentenones 210215 and 212.216... 

Development of the catalytic Pauson-Khand reaction. One disadvantage of the PK reaction, as first reported, was its need for stoichiometric amounts of dicobalt octacarbonyl. In order to make the reaction more attractive, both synthetically and environmentally, efforts were made to reduce the quantities of the transition metal species, although this often led to the requirement for high pressures of CO in order to obtain respectable yields. 

Their retro synthetic study was based around the Pauson-Khand cyclization (6), which couples an alkene, an alkyne, and a carbon monoxide source (typically dicobalt octacarbonyl) to give a cyclopentenone ring (Fig. 3.5, top). This reaction has been widely used for synthetic purposes, and some excellent reviews (7,8) have covered its principal features and the recent improvements to its experimental conditions. This reaction, in its intramolecular version, is ideal for the assembly of the l//-[2]pyrindi-none scaffold in two distinct versions, differing in the stereochemistry of the ring junction (Fig. 3.5, bottom). Hence, the readily available unsaturated amino acid derivatives 3.1a,b undergo intramolecular Pauson-Khand reaction to produce the two unsamrated scaffolds 3.2a,b. 

Cyclopropene can also be used as the aUcene component and affords bicyclo[3.1.0]hexen-2-ones upon reaction with alkyne dicobalt octacarbonyl complexes in the presence of NMO (Scheme 250). Vinyl ethers and vinyl esters serve as ethene equivalents in Pauson-Khand reactions. For example, reaction of vinyl benzoate with complex (169) furnished cyclopentenone (170) (Scheme 251). This reaction was used in a synthesis of (-l-)-taylorine and nortaylorine. Allenes participate in intermolecular Pauson-Khand reactions affording alkylidene-substituted cyclopentenones (Scheme 252). ... 

Pauson-Khand reaction. Cobalt is deposited by decomposing dicobalt octacarbonyl in refluxing toluene in the presence of mesoporous silica. The substance is active as a heterogeneous catalyst for the Pauson-Khand reaction. A related catalyst is cobalt-on-carbon, which can be used at least 10 times with yields maintaining at the 95% level. ... 

An interesting cyclization reaction was reported that involved the reaction of dienes, diynes, or ene-ynes with transition metals to form cyclopentenone derivatives in the presence of carbon monoxide.363 in a simple example, ene-yne 444 was heated with dicobalt octacarbonyl and CO to give a 68% yield of 445.364 jjjj transformation has become an important synthetic tool known as the Pauson-Khand reaction.365 jhe mechanism probably involves insertion of the alkene (or alkyne) into the transition metal bond, which is why it is presented in this section. Formally, it is a [2+2+l]-cycloaddition, but the accepted mechanism is the one proposed by Magnus,364 and shown in Figure 13.8.366 n has been stated that further study is required to... 

This reaction has found its way into organic synthesis fi and is attractive because of its generality and selectivity. In Drummond s synthesis of hydroxymethylacylfulvene,3 0 for example, a Pauson-Khand reaction of the allene-alkyne 446 gave a 69% yield of 447. In this case, molybdenum hexacarbonyl was used. In Takano s synthesis of dendrobine, 448 was treated with dicobalt octacarbonyl and then NMO to give an 89%... 

The Pauson-Khand reaction is the formation of cyclopentenones 486 by the action of dicobalt octacarbonyl on an alkyne, followed by an alkene. The process involves the intermediacy of cobalt complexes 485 (equation 53). (For reviews, see References 302 and 303.) Terminal alkynes, including acetylene and arylacetylenes, give better yields than internal acetylenes. An example of an intramolecular Pauson-Khand reaction is the conversion of the enyne 487 into the cyclopentanocyclopentenone 488 ". ... 

AstraZeneca published the use of an immobilized transition metal carbonyl complex as a catalyst in the Pauson-Khand reaction [67]. This reaction is known to produce useful products but it also suffers from a number of drawbacks dicobalt octacarbonyl and its analogs are volatile, toxic, and unstable due to loss of carbon monoxide and aerial oxidation. These drawbacks can be avoided by the use of an immobilized metal carbonyl complex (Scheme 13), which is safe and convenient to handle (see also [68]). It offers the additional advantages of being reusable after recovery from the reaction medium and the product becomes less contaminated with metal carbonyl remnants. The reaction was applicable to a wide range of substrates with the exception of tetra-substituted alkenes. A typical reaction of enine 32 to the bicyclic enone 33 is depicted in Scheme 13. 

A significant advance in the Pauson-Khand reaction was made by the discovery that various additives, such as tertiary amine A-oxides, promote the cycloaddition reaction. For example, treatment of the dicobalt complexed alkyne 187 with trimethylamine A-oxide at only 0 °C provides the cyclopentenone 188 in good yield (1.192). More recent advances have been made in catalytic Pauson-Khand reactions. " Only 3 mol% of dicobalt octacarbonyl [Co2(CO)8] under one atmosphere of CO effects the formation of the cyclopentenone 188 from the alkyne 189 in benzene at 70 °C (an improvement in the yield to 90% was achieved in the presence of the additive Bu3P=S) (1.193). " ... 

The Pauson-Khand reaction provides another new approach to the metal-catalyzed synthesis of heterocycles. This reaction involves the interaction of the multiple bonds of an alkyne with an alkene and carbon monoxide in the presence of dicobalt octacarbonyl (Co2(CO)g), or with just this reagent as a source of CO. The overall process has been described as a [2 -h 2 -h 1] cycloaddition. Only a few applications to heterocyclic synthesis have been reported so far. A 2008 paper that is illustrative of the process describes the use of this reaction for the construction of a heterocyclic ring that is part of an azabicy-clo[3.3.1]nonane derivative. This ring system is present in the alkaloid (-)-alstonerine (4.37), which prompted this study. 

The reaction was first reported by Khand and Pauson et al. in 1973d It is the dicobalt octacarbonyl [Co2(CO)8l mediated or promoted one-step synthesis of a,p-unsaturated cyclopentenone from the [2+2+1] cycloaddition of alkyne, alkene and carbon monoxide, through an intermediate of alkynedicobalt hexacarbonyl complex. Therefore, this reaction is generally known as the Pauson-Khand reaction, Pauson-Khand cyclization, or Pauson-Khand cycloaddition. Occasionally, this reaction is also referred to as the Pauson-Khand annulation, Pauson-Khand multicomponent cycloaddition, Pauson-Khand carbonylative cocyclization, Pauson-Khand bicyclization, Khand annulation, Khand cycloaddition, Khand cyclization (cyclisation ), or Khand reaction.Among these names, the Pauson-Khand reaction is the one used most often. 

The Pauson-Khand reaction is a recent addition to the armamentarium of synthetic organic chemistry. In this process, a carbonyl group (provided initially as a ligand attached to dicobalt octacarbonyl [Co2(CO)g]) bridges an alkyne to an alkene to produce, finally, a cyclopentenone. While many of the details of the process remain sketchy, a general outline of the process is provided in Scheme 9.92. 

The dicobalt octacarbonyl catalysed the three-component reaction of alkene, alkyne and carbon monoxide to give cyclopentenone, which was an important breakthrough in organic synthesis [8]. A three-component direct condensation to yield rings or fragments was very difficult earlier to the estabhshment of the Pauson-Khand reaction. 

Reaction of [S(CCPh)2] with [Co2(CO)g] afforded 2 jhe crystallographically characterised adduct [(PhCC)S Co2(CO)6(Ti2-CCPh) ] which, on treatment with further [Co2(CO)g] afforded [S Co2(CO)6(Tl2-CCPh) 2l. The reaction of pentacarbonyl allyloxy((4-methylphenyl)ethynyl)carbene) chromium and tungsten complexes with dicobalt octacarbonyl afforded 63 tpe alkyne complexes (62) (M = Cr, W), which failed to undergo intramolecular Pauson-Khand reactions instead, at room temperature, a 1,2-elimination occurs, regenerating the metal hexacarbonyl with predominant formation of dinuclear cobalt complexes (63) - (65). 

Apart from cobalt carbonyl catylyzed hydroformylation, Pauson-Khand (PK) reaction is another type of reaction catalyzed with bimetallic carbonyl complex. Formally Pauson-Khand (PK) is a [2 -i- 2 -i- 1] cycloaddition of an alkyne, an alkene, and a CO group into cyclopentenone [128-130]. This process was initially discovered in 1973 [131], and early studies focused on using dicobalt octacarbonyl as both reaction mediator and the source of the carbonyl functional group. Since several variants of the original thermal protocol were introduced, PK reaction has received more and more fundamental and organic synthesis interests [132, 133]. 

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