Arbuzov reactions, carbon-phosphorus

The use of an electron-rich trivalent phosphorus center for addition to or substitution at an electrophilic site is a long-established approach to the formation of carbon-phosphorus bonds. The classical studies of the Michaelis-Arbuzov, Michaelis-Becker, Abramov, Pudovik, and related reactions and their mechanisms and synthetic utilities have been thoroughly reviewed. In this chapter, we present only a brief introduction to these reactions and provide several examples of their more facile uses from the older literature. More attention is given to relatively recent developments regarding such reactions that are seen as improvements in their general utility. 

The use of transition metals for the facilitation of substitution reactions on vinylic carbon has proven to be quite successful. For example, vinylic chlorides in the presence of nickel(II) chloride react with trialkyl phosphites to substitute phosphorus for the halide (Figure 6.17j.71-72 While reminiscent of a direct Michaelis-Arbuzov reaction, including final dealkylation by a chloride ion, the reaction actually involves an addition-elimination process. It appears that chloride provides a more facile reaction than bromide, a characteristic noted in several reaction systems. 

Sugars containing a carbon-phosphorus bond have been prepared by application of the Michaelis-Arbuzov reaction to bromodeoxy sugars. Thus, the reaction of 5-bromo-5-deoxy-l,2-0-isopropylidene-3-O-methyl-a-D-xylofuranose (131) with triethyl phosphite yields the corresponding diethyl phosphonate (132) compound 132 was employed for the synthesis of a sugar derivative having phosphorus as... 

In spite of many previous studies on the mechanisms by which trialkyl phosphites interact with a -halogenocarbonyl compounds, the reactive intermediates which lead to ketophosphonate (Arbuzov reaction) and to vinyl phosphate (Perkow reaction) have in no cases been clearly identified. It is generally believed (JL), however, that the Arbuzov product 4 results from initial attack by phosphorus at the cf-carbon atom, whereas the Perkow product 7 is formed by initial attack at the carbonyl carbon atom, followed by migration of phosphorus from carbon to oxygen (Scheme 1). 

Quasiphosphonium ions involving oxygen directly bound to the positive phosphorus site are generated as intermediates in numerous other reactions. For example, the Michaelis-Arbuzov reaction (see Section 3.5) produces a quasiphosphonium ion as an intermediate that undergoes attack by the associated amon at the carbon end of the C T P linkage. The reaction follows a different course when aryl ester linkages are present on the starting trivalent phosphorus acid derivative. In such instances, a quasiphosphomum ion is... 

From a synthetic viewpoint, the significant feature of the classical Michaelis-Arbuzov reaction of an alkyl halide with a P(III) ester is the formation of a carbon-phosphorus bond. Since its discovery by Michaelis and Kaehne (222) in 1898, it has been the principle synthetic route to the phosphonic acids, which, with their esters and amides, probably outnumber all other compounds containing the carbon-phosphorus bond (105). 

It is evident that the interaction of a phosphorus(III) triester and the alkylating species RX can be pictured as an S 2 process (reaction 2) or, for those alkylating reagents capable of forming a carbocation, as an S l process (reaction 3). Several reactions testify to the importance of carbocationic carbon for the Michaelis-Arbuzov reaction in pursuance of its normal course they include the ease of reaction of cyclopropene dihalides, already encountered, and the ready formation of complexes with species having particularly weakly nucleophilic counter ions. Phosphonic acid formation also takes place with cyclic azonium salts and related ions. 9-Chloroacridine reacts with triethyl phosphite to afford a product thought to be the bisphosphonic acid ester 49 The related phosphonic esters 51 are obtainable when the onium salts 50 (X = NH, NR, O or S) are treated with trimethyl... 

In contrast to the general lack of reactivity of ethenyl halides under Michaelis-Arbuzov conditions, except in catalysis by nickel(II), the formation of bonds from phosphorus to sp -carbon is observed when polyfluoroalkenes take part in Michaelis-Arbuzov reactions. 

Other examples of modification in the Michaelis-Arbuzov reaction in the formation of phosphorus-carbon bonds in compounds other than esters are reactions between dichlorophosphites " or difluorophosphites and organic halogen-containing compounds in the presence of iron(III) chloride (reactions 2 and 3). A similar reaction takes place with diethyl fluorophosphite A further variation is that of the photoinitiated reaction, a... 

Although those Michaelis-Arbuzov reactions which involve acyl halides and phospho-rus(III) esters are yet a further route to phosphorus-carbon bond formation and will be discussed later in Section VI, the use of halogenated acyl halides has led to some unusual results which, conveniently, can be summarized here. The products obtained from reactions between trialkyl phosphites and perfluoroacyl chlorides contain both phosphonate and phosphate moieties and are structurally dependent on reaction temperature. The initial product (Scheme 4) is thought to be the ylide 66. In an ethereal solvent at low temperature, decomposition of the ylide yields [l-(dialkoxyphosphinoyl)oxy-l/f-perfluo-roalkyl]phosphonates (67) exclusively, but at -20 °C and above, and in the absence of a solvent, the products consist of (Z)-[l-(dialkoxyphosphinoyl)oxyperfluoroalkene]phos-phonates (68) . The treatment of the compounds 67 with Ida yields 68, and the action of BuLi-CuI on 68 results in loss of the phosphate moiety to give the esters 69 The structural isomers 70 of the compounds 68 have been obtained as illustrated in equation... 

A simple and efficient route to a variety of structures containing phosphorus-carbon bonds, under mild conditions and in good chemical yields, has been developed by Michalski and co-workers. Halotrimethylsilanes MesSiX (X = Br, I) catalyzed rearrangements of tricoordinate phosphorus esters (584) into the corresponding phosphoryl systems (585) (Scheme 144). Experimental evidence indicated that the mechanisms of the reactions were fundamentally different from that of the Michaelis-Arbuzov reaction. 

Phosphorus reagents are an integral part of modern organic chemistry, so weTl devote the next few sections to discuss some of the most instructive aspects of organophosphoms chemistry. We ll begin with the Michaelis-Arbuzov reaction, which is a powerful means of creating a carbon-phosphorus bond and hence a key route to organophosphoms chemistry. The reaction involves the interaction of an alkyl halide and a trialkyl phosphite ... 

Carbon-phosphorus bonds are formed by the Pd-catlyzed allylation of various phosphorus compounds (Scheme 13). The reaction of l-acetoxy-2-cyclohexene with LiPPh2 in refluxing THF provides an allylic phosphine in low yield (<15%). The phosphine produced deactivates the catalyst by coordination, which lowers the yield. In contrast, the reaction of LiP(S)Ph2 with l-acetoxy-2-cyclohexene takes place at room temperature to give allylic diphenylphosphine sulfides in 85% yield. ° Pd-catalyzed Michaelis-Arbuzov reaction of cinnamyl acetate with trimethyl phosphite affords a dimethyl allylic phospho-nate. With the reaction conditions being rather severe, this method may not be applicable to an allylic acetate that can produce a conjugated diene via /3-hydride elimination from the intermediate 7r-allylpalladium complex. 

Group VII. The rate law for reaction of PhaM—Mn(C0)6, where M = Si, Ge, or Sn, with a variety of nitrogen and phosphorus bases, both unidentate (e.g. phosphines) and bidentate (e.g. diphos, bipy), indicates parallel dissociative and associative mechanisms in all cases. This assignment of mechanisms on the basis of the rate law is supported by activation entropies determined for the respective terms. Exceptionally, the reaction of PhaSi—Mn(CO)s with trialkyl phosphites does not result in simple substitution of carbon monoxide by the phosphite, but produces trans-Mn(COR)(CO)s[P(OR)3]2 by way of a Michaelis-Arbuzov reaction. ... 

Arbuzov and Michaelis-Becker reactions provide facile and versatile procedures for the formation of carbon-phosphorus bonds. These methods, however, are not applicable to the formation of sp hybridized carbon-phosphorus bonds. Only few methods have been reported for the syntheses of arylphosphonates and vinylphospho-nates. Direct reaction of aryl or vinyl halides with trialkyl phosphite in the presence of nickel halide requires severe reaction conditions [21,22], and the stereochemistry of vinylphosphonates has not been clarified. Synthesis of dialkyl arylphosphonates 22 [23, 24] is achieved by the palladium-catalyzed reaction (Scheme 2.12), which is called by Hirao reaction . The stereoselective synthesis of dialkyl vinylphosphonates 23 [24-26] is similarly accomplished by this method (Scheme 2.13). A variety of modified procedures have been developed recently [27-37]. 

Fundamentally, the Michaelis-Becker reaction, and the first step in the mechanism of the Arbuzov reaction, involves 8 2 substitution at the carbon atom and as such should lead to stereospecific formation of the C—P bond (with inversion of configuration at the carbon atom) when chiral alkyl halides are used. Secondary alkyl halides, in most cases, favor elimination instead of substitution, in contrast to epoxides that react with phosphorus nucleophiles without elimination and with excellent stereoselectivity. The later reaction was successfiiUy used in a synthesis of glycosylphosphonate analog 3 of T>-myo-inositol-1,4,5-triphosphate (Scheme 47.2). ... 

For example, in the instance of 9-chloroacridine, the attachment of the halogen (leaving group) at a suitably electrophilic carbon site allows the occurrence of a replacement reaction, presumably occurring via an addition-elimination procedure for phosphorus attachment, followed by the common nucleophilic displacement (ester cleavage) of the Michaelis-Arbuzov process (Figure 6.1).4... 

Recently we have developed a more general approach to molecules exemplified by III. Thus the Diels-Alder cycloaddition of alkyne II and ct-pyrone, followed by aromatization by loss of carbon dioxide, led to the isolation of III (72%) (5). Alkyne II was obtained in high yields, in two steps from dichloroacetylene and triethylphosphite via Arbuzov-type reactions (5). Since the intermediate chloroalkyne phosphonate I was isolable (90%), phosphorus nucleophiles other than triethylphosphite could be used to give unsymmetrical alkyne diphosphoryl species. We have demonstrated this approach by the reaction of I with PhaPOEt and PhP(OEt)2 (5). 

The mechanism of the Perkow reaction has been a subject of some debate but is now generally thought to proceed by initial attack of phosphorus at the carbonyl carbon atom, not by rearrangement of a Michaelis-Arbuzov intermediate 5.77,78... 

The reaction is presumed to occur by initial formation of HjfMenO) PO], which then undergoes direct P-alkylation by nucleophilic attack of phosphorus on carbon with displacement of halide. An alternative alkylation mechanism involving nucleophilic attack of oxygen on carbon, followed by a Michaelis-Arbuzov rearrangement i) of a dialkyl phenylphosphonite (C6H5(MenO)POR) intermediate with the alkyl halide was effectively eliminated by the observation that reaction of methyl phenylphosphinate with a tenfold excess of methyl-c/3 iodide gave the product distribution shown in Eq. (2). 

A reaction having significant synthetic importance for the construction of dialkyl 2-formylaIkyl-phosphonates involves the addition of trivalent phosphorus reagents to a,3-unsaturated aldehydes. s This Michael-Michaelis-Arbuzov strategy is the method of choice for incorporating, from readily available Michael-type substrates, one or two substituents at any position of the carbon chain between the phosphoryl and formyl groups. 

The reaction between trialkyl phosphites and a,P-unsaturated nitriles has been less thoroughly investigated. Whereas the hydrophosphonylation of unsaturated nitriles with diakyl phosphites proceeds smoothly, the addition of trialkyl phosphites requires more severe conditions. It involves the nucleophilic attack by the trivalent phosphorus reagent at the tenninal carbon atom of the conjugated system followed by valency expansion of phosphorus in agreement with the Michaelis-Arbuzov mechanism (Scheme 6.27). - ... 

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