Alkyne-alkene-carbonyl Pauson-Khand reaction

Abstract The transition metal mediated conversion of alkynes, alkenes, and carbon monoxide in a formal [2 + 2+1] cycloaddition process, commonly known as the Pauson-Khand reaction (PKR), is an elegant method for the construction of cyclopentenone scaffolds. During the last decade, significant improvements have been achieved in this area. For instance, catalytic PKR variants are nowadays possible with different metal sources. In addition, new asymmetric approaches were established and the reaction has been applied as a key step in various total syntheses. Recent work has also focused on the development of CO-free conditions, incorporating transfer carbonylation reactions. This review attempts to cover the most important developments in this area. 

Several reports have appeared on the effect of additives on the Pauson-Khand reaction employing an alkyne-Co2(CO)6 complex. For example, addition of phosphine oxide improves the yields of cyclopentenones 119], while addition of dimethyl sulfoxide accelerates the reaction considerably [20]. Furthermore, it has been reported that the Pauson-Khand reaction proceeds even at room temperature when a tertiary amine M-oxide, such as trimethylamine M-oxide or N-methylmorpholine M-oxide, is added to the alkyne-Co2(CO)6 complex in the presence of alkenes [21]. These results suggest that in the Pauson-Khand reaction generation of coordinatively unsaturated cobalt species by the attack of oxides on the carbonyl ligand of the alkyne-Co2(CO)6 complex [22] is the key step. With this knowledge in mind, we examined further the effect of various other additives on the reaction to obtain information on the mechanism of this rearrangement. 

Alkyne-alkene carbonylative coupling. Intramolecular carbonylative coupling of dialkynes catalyzed by Fe(CO)3 provides a route to cyclopentadienones (equation I). The more difficult carbonylative alkyne-alkene coupling to provide cyclopen-tenones (Pauson-Khand reaction) can also be effected with Fe(CO)s, but in modest yield. In an improved coupling, acetone is treated with Fe2(CO)9 to form Fe-... 

The Pauson-Khand reaction starts with the replacement of two CO molecules, one from each Co atom, with the alkyne to form a double a complex with two C-Co a bonds, again one to each Co atom. One CO molecule is then replaced by the alkene and this n complex in its turn gives a a complex with one C-Co a bond and one new C-C a bond, and a C-Co bond is sacrificed in a ligand coupling reaction. Then a carbonyl insertion follows and reductive elimination gives the product, initially as a cobalt complex. 

Pauson-Khand Cycloaddition. Pauson Khand cycloaddition (see Pauson-Khand Reaction) is a cobalt-mediated method to prepare cyclopentenone from the cyclization of an alkyne with an alkene and CO (equation 14). This method is widely used to produce cychc ketones. Originally, stoichiometric amounts of Co2(CO)g were used in these reactions with the cobalt carbonyl being the CO source. However, it was shown that a strict temperature profile and high-purity reagents allowed the use of catalytic amounts of Co2(CO)g for reactions with 1 atm of CO. Currently, there is intense interest in developing catalytic cobalt starting materials for use in Pauson-Khand reactions. 

The Pauson-Khand reaction gives the same product as the group 4 metal-mediated reductive coupling and carbonylation, and both reactions proceed by essentially the same mechanism formation of an alkyne-metal tt complex, insertion of an alkene, insertion of CO, and reductive elimination. Some details differ, however. When an alkyne is added to Co2(CO)g, CO evolves, and an isolable, chromatographable alkyne-Co2(CO)6 complex is obtained. This butterfly complex contains four Co(II)-C bonds, and the Co-Co bond is retained. The formation of the alky n e-C o2 (C O) 6 complex involves the formation of an ordinary tt complex of the alkyne with one Co(0) center, with displacement of CO. The tt complex can be written in its Co(II) cobaltacyclopropene resonance structure. The tt bond of the cobaltacyclopropene is then used to form a tt complex to the other Co center with displacement of another equivalent of CO. This second tt complex can also be written in its cobaltacyclopropene resonance structure. The alkyne-Co2(CO)6 complex has two 18-electron Co(II) centers. 

In a similar manner, cyclopropane-containing benzvalene can be used as the alkene component in intermolecular Pauson-Khand reactions.Several examples of intermolecular Pauson-Khand cyclizations of methylenecyclopropanes and alkynes are reported to give bicyclic car-bocycles. Ethynylcyclopropyl-substituted chromium carbonyl complexes have also been used in palladium-catalyzed coupling reactions. 

In chapter 6 we described the use of the remarkable Pauson-Khand reaction for the synthesis of cyclopentenones. If the components (CO, alkene and alkyne) are tethered by a nitrogen atom, a heterocycle will also be formed. The first stage in this process is to couple the cobalt carbonyl complex, e.g. 236, of ahalo-alkyne with an amine containing the alkene in the side chain. The best way to do this is to react 234 with Co2(CO)9 to give 235 and then 236 and to capture this complex with the amine without isolation of intermediates.34... 

Besides [m + n] cycloadditions and [m 4- m + m +. ..] cyclo- and cocyclooligomerizations of alkenes, dienes or alkynes (see Sections 1.5.8.3.5, and 1.5.8.3.6.), transition metal complexes can also catalyze the cycloaddition of more than two different components. Most important is carbonylative ring synthesis with carbon monoxide as the C, unit. Several methods of this type use transition metals stoichiometrically, others catalytically. For some of the stoichiometric methods, developments towards catalytic versions are under way (e g., the Pauson-Khand reaction, see below). 

Production of the tetrasubstituted cyclopentenone (15a, 15b)) involves condensing the protected vinyl ether (16) with (12) via a Pauson-Khand reaction. Studies on the Pauson-Khand reaction , 1 have shown that upon condensing an unsymmetrical alkene with an unsymmetrical alkyne in the presence of a cohalt carbonyl compound give rise to mixtures of diastereomers (Fig 1) with the bulkier substituents of the alkene and alkyne being a to the carbonyl of the cyclopentenone. However, the stereochemistry a to the... 

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. 

Chapter 17 closes with a brief presentation of the Pauson-Khand reaction. The Pauson-Khand reaction (PKR) is a formal [2+2+1] cycloaddition reaction involving an alkyne, an alkene, and carbon monoxide to form a cyclopentanone shown generically in Equation 17.71. The Pauson-Khand reaction was initially reported as a stoichiometric reaction mediated by cobalt carbonyl, but it has been translated into a catalytic process in recent years. Most recently, it has developed into an enantioselective catalytic process. Complexes of Ti, Mo, W, Fe, Co, Ni, Ru, Rh, Ir, and Pd have all been shown to catalyze this reaction. 

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 carbonylation reactions are very important in synthesis and for industrial applications as well. The Pauson-Khand reaction, the well-known cobalt-mediated procedure, combines an alkyne, an alkene, and a carbon monoxide ligand into cyclopentenones (Eq. 39) [36]. 

Cyclization of an alkyne to an alkene with carbonyl insertion (analogous to the Pauson-Khand reaction) has also been achieved using pentacarbonyliron. ... 

Among the carbonylative cycloaddition reactions, the Pauson-Khand (P-K) reaction, in which an alkyne, an alkene, and carbon monoxide are condensed in a formal [2+2+1] cycloaddition to form cyclopentenones, has attracted considerable attention [3]. Significant progress in this reaction has been made in this decade. In the past, a stoichiometric amount of Co2(CO)8 was used as the source of CO. Various additive promoters, such as amines, amine N-oxides, phosphanes, ethers, and sulfides, have been developed thus far for a stoichiometric P-K reaction to proceed under milder reaction conditions. Other transition-metal carbonyl complexes, such as Fe(CO)4(acetone), W(CO)5(tetrahydrofuran), W(CO)5F, Cp2Mo2(CO)4, where Cp is cyclopentadienyl, and Mo(CO)6, are also used as the source of CO in place of Co2(CO)8. There has been significant interest in developing catalytic variants of the P-K reaction. Rautenstrauch et al. [4] reported the first catalytic P-K reaction in which alkenes are limited to reactive alkenes, such as ethylene and norbornene. Since 1994 when Jeong et al. [5] reported the first catalytic intramolecular P-K reaction, most attention has been focused on the modification of the cobalt catalytic system [3]. Recently, other transition-metal complexes, such as Ti [6], Rh [7], and Ir complexes [8], have been found to be active for intramolecular P-K reactions. 

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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