Transfer carbonylation

Cationic Fp (olefin) complexes [Fp = f/5-C5H5Fe(CO)2] undergo regio-specific addition of heteroatomic nucleophiles.32 Subsequent ligand transfer (carbonyl insertion) occurs with retention of configuration at the migrating center (R—Fe—CO -> RCOFe).33 A combination of these processes has provided a novel stereospecific azetidinone synthesis which can also be applied to condensed systems.34... 

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. 

Scheme 2 Proposed catalytic mechanism for PK transfer carbonylations...

Recent developments have impressively enlarged the scope of Pauson-Khand reactions. Besides the elaboration of strategies for the enantioselective synthesis of cyclopentenones, it is often possible to perform PKR efficiently with a catalytic amount of a late transition metal complex. In general, different transition metal sources, e.g., Co, Rh, Ir, and Ti, can be applied in these reactions. Actual achievements demonstrate the possibility of replacing external carbon monoxide by transfer carbonylations. This procedure will surely encourage synthetic chemists to use the potential of the PKR more often in organic synthesis. However, apart from academic research, industrial applications of this methodology are still awaited. 

Another useful reaction for the difunctionalization of olefins involves a group transfer carbonylation starting from a a-(phenylseleno)carbonyl (or related derivatives) and a terminal alkene under 80 atm of CO. An alkyl radical is first formed by the photocleavage of a C-SePh bond. The addition of this radical to the olefin, followed by the incorporation of CO and radical coupling with PhSe-, gave substituted selenoesters via a three-component coupling reaction [74], The intermolecular formation of C—C bonds via phenylseleno group transfer has been likewise adopted in the reaction between ester-substituted O,Se-acetals and an olefin [75],... 

Ryu, I., Muraoka, H., Kambe, N., Komatsu, M., and Sonoda, N. (1996) Group transfer carbonylations photoinduced alkylative carbonylation of alkenes accompanied by phenylselenenyl transfer. Journal of Organic Chemistry, 61, 6396-6403. 

Bis(triphenylphosphine)palladium dichloride [(Ph3P)2PdCl2] can also be used as a catalyst for the phase-transfer carbonylation of halides. However, considerably more drastic conditions [95°C, 5 atm] are required when compared with Co2(CO)8 (44). The carbonylation of allyl chlorides can be catalyzed by nickel tetracarbonyl, giving isomeric mixtures of bu-tenoic acids. There is evidence for the intermediacy of polynuclear nickel-ates in this phase-transfer process (45). Acetylene insertion did not occur... 

A Pauson-Khand type reaction of enynes, where the CO source is an aldehyde, has been reported by Morimoto and coworkers. This CO-transfer carbonylation system was carried ont with monomeric or dimeric rhodium complexes supported by monodentate or chelating phosphine ligands (e g. [RhCl(cod)]2/dppe or dppp [RhCl(CO)PPh3]). This reaction is snccessfiil for a series of enynes and aldehydes (Scheme 28). 

O—O and C—C homolysis and group transfer carbonyl -I- alkene (one rearranged) -I- OH... 

Up until the end of the 1980s, radical carbonylation chemistry was rarely considered to be a viable synthetic method for the preparation of carbonyl compounds. In recent years, however, a dramatic change has occurred in this picture [3]. Nowadays, carbon monoxide has gained widespread acceptance in free radical chemistry as a valuable Cl synthon [4]. Indeed, many radical methods can allow for the incorporation of carbon monoxide directly into the carbonyl portion of aldehydes, ketones, esters, amides, etc. Radical carboxylation chemistry which relies on iodine atom transfer carbonylation is an even more recent development. In terms of indirect methods, the recent emergence of a series of sulfonyl oxime ethers has provided a new and powerful radical acylation methodology and clearly demonstrates the ongoing vitality of modem free radical methods for the synthesis of carbonyl compounds. 

The photolysis of a-phenylselenoacetate and related compounds in the presence of an alkene and CO leads to acyl selenides via group transfer carbonylation. The mechanism of this three-component coupling reaction involves the addition of an a-(alkoxycarbonyl)methyl radical to an alkene, the trapping of the produced alkyl free radical by CO, and termination of the reaction by a phenylselenenyl group transfer from the starting material (Scheme 4-43) [73]. 

Atom transfer carbonylation of 3-iodo alcohols provides a useful method for the synthesis of five-membered ring lactones (Scheme 4-49) [85]. The method is also applicable to six- and seven-membered ring lactones. 

Photolysis of methyl a-(phenylseleno)acetate in the presence of diallyl ether and carbon monoxide leads to the acyl selenides via radical cyclization and group transfer carbonylation (Scheme 15.49) [124]. 

Recent work has shown that the AIBN/allyltin system serves as an efficient radical initiator system which can be used as an alternative for light-induced atom transfer carbonylation [42b, 57]. 

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