2« cyclobutanone alkene

Scheme 6 Rh-catalyzed intramolecular cyclobutanone-alkene coupling...

In the presence of a double bond at a suitable position, the CO insertion is followed by alkene insertion. In the intramolecular reaction of 552, different products, 553 and 554, are obtained by the use of diflerent catalytic spe-cies[408,409]. Pd(dba)2 in the absence of Ph,P affords 554. PdCl2(Ph3P)3 affords the spiro p-keto ester 553. The carbonylation of o-methallylbenzyl chloride (555) produced the benzoannulated enol lactone 556 by CO, alkene. and CO insertions. In addition, the cyclobutanone derivative 558 was obtained as a byproduct via the cycloaddition of the ketene intermediate 557[4I0]. Another type of intramolecular enone formation is used for the formation of the heterocyclic compounds 559[4l I]. The carbonylation of the I-iodo-1,4-diene 560 produces the cyclopentenone 561 by CO. alkene. and CO insertions[409,4l2]. 

Abstract The photoinduced reactions of metal carbene complexes, particularly Group 6 Fischer carbenes, are comprehensively presented in this chapter with a complete listing of published examples. A majority of these processes involve CO insertion to produce species that have ketene-like reactivity. Cyclo addition reactions presented include reaction with imines to form /1-lactams, with alkenes to form cyclobutanones, with aldehydes to form /1-lactones, and with azoarenes to form diazetidinones. Photoinduced benzannulation processes are included. Reactions involving nucleophilic attack to form esters, amino acids, peptides, allenes, acylated arenes, and aza-Cope rearrangement products are detailed. A number of photoinduced reactions of carbenes do not involve CO insertion. These include reactions with sulfur ylides and sulfilimines, cyclopropanation, 1,3-dipolar cycloadditions, and acyl migrations. 

Ketenes have cnmnlative bonds and can undergo [2+2] cycloaddition reactions across C=C and C=0 bonds. Interestingly, most of the prodncts obtained are cyclobutanones rather than oxetanes. Thermal [2+2] cycloaddition reactions in the pseudoexcitation band occur between electron donors and acceptors. Alkenes are donors while ketenes are acceptors. In contrast to the experimental observations. 

Cycloaddition reactions of ketenes with alkenes have long been known to give cyclobutanones [123] and to proceed with retention of the configurations [124], The reactions were classified into the symmetry-allowed cycloaddition reactions... 

Cycloadditions of ketenes and alkenes have synthetic utility for the preparation of cyclobutanones.163 The stereoselectivity of ketene-alkene cycloaddition can be analyzed in terms of the Woodward-Hoffmann rules.164 To be an allowed process, the [2ir + 2-tt] cycloaddition must be suprafacial in one component and antarafacial in the other. An alternative description of the TS is a 2irs + (2tts + 2tts) addition.165 Figure 6.13 illustrates these combinations. Note that both representations predict formation of the d.v-substituted cyclobutanone. 

Ketenes are especially reactive in [2 + 2] cycloadditions and an important reason is that they offer a low degree of steric interaction in the TS. Another reason is the electrophilic character of the ketene LUMO. As discussed in Section 10.4 of Part A, there is a large net charge transfer from the alkene to the ketene, with bond formation at the ketene sp carbon mnning ahead of that at the sp2 carbon. The stereoselectivity of ketene cycloadditions is the result of steric effects in the TS. Minimization of interaction between the substituents R and R leads to a cyclobutanone in which these substituents are cis, which is the stereochemistry usually observed in these reactions. 

A series of 2-vinyl-3-silyloxybicyclo[3.2.0]heptan-6-ones has also been converted to prostanoid lactones in excellent yield but variable regioselectivity. Some of the best regioselectivity was obtained using H202 in trifluoroethanol (see p. 1097).241 The strained cyclobutanone ring and the relatively unreactive terminal vinyl group favor the desired reaction in preference to alkene epoxidation. 

As invented by Wender,196,197 a variant of the second transformation can take place if the alkene partner is substituted by a participating group such as a strained cyclopropyl or a cyclobutanone (in the case of a 1,6-diene).198 The whole process, which mainly relies on the use of rhodium or ruthenium complexes,1 9 results in the formal... 

The substituent effects on the alkene were investigated in the reaction of enyne 12 and chromium carbene complex 2c [8]. In the reaction of enyne -12a having a phenyl group on the alkene with Fischer chromium carbene complex 2c, metathesis product 13a was obtained as a main product along with cyclopropane 14 and cyclobutanone 15 (Eq.4). The reaction of Z-12a with 2c gave only... 

Cyclobutanones (11, 560-561). Ketenimium salts are more reactive than ke-tenes in [2 + 2] cycloadditions with alkenes to prepare cyclobutanones. The salts are readily available by in situ reaction of tertiary amides with triflic anhydride and a base, generally 2,4,6-collidine. The cycloaddition proceeds satisfactorily with alkyl-substituted alkenes and alkynes, but not with enol ethers or enamines.1... 

Using (-)-lOO [46] as a chiral auxiliary tethered to the enolether, one face of the alkene can be specifically blocked by a n-n interaction of the phenyl rest for the [2 r5+2 r ] cycloaddition with a ketene [47], resulting in the highly diastereoselective formation of the cyclobutanone 102 (Scheme 15). The observed regio- and stereoselectivity is in accord with the stereochemical predictions made on the basis of the Woodward-Hoffmann... 

Fig. 6.6. HOMO-LUMO interactions in the [2 + 2] cycloaddition of an alkene and a ketene. (a) Frontier orbitals of alkene and ketene. (b) [2ks + 2na Transition state required for suprafacial addition to alkene and antarafacial addition to ketene, leading to R and R in cis orientation in cyclobutanone products, (c) [2ns + (2ns + 271,)] alternative transition state.

Ketene acetals and thioacetals can be used as ketene equivalents in cyclobutanone synthesis in situations where ketene to alkene cycloadditions are inefficient such as in the case of electron-deficient alkenes.14 Although thermal cycloadditions of ketene acetals and thioacetals with electron-deficient alkenes have been observed (see Section 1,3.2.1.), such cycloadditions proceed more efficiently and under milder conditions with metal catalysts. Efficient cycloadditions between ketene dimethyl acetal and alkenes substituted by a single electron-withdrawing group have been reported.15... 

Steroids represent rigid chiral systems which are convenient substrates for mechanistic studies of geometric details. Early studies on the difacial selectivity of ketene to steroidal alkene cycloadditions led to the preparation of optically pure cyclobutanones. The addition of dichloroketene to 2- or 3-methyl-5a-cholcst-2-ene (1) generates the cyclobutanones 2 and 3 with regio- and stereoselectivity. The cycloadditions proceed to give the adducts resulting from ketene approach to the a-face.4... 

Ketcnc equivalents, such as ketene acetals and thioacetals, can be used in cycloadditions to electron-deficient alkenes (see Sections 1.3.2.1. and 1.3.2.2.). In an example of a fumaric acid diester fitted with two chiral alcohol auxiliary groups, the aluminum(III)-catalyzed cycloaddition of 1,1-dimethoxyethene with di-(—)-menthyl fumarate (9) proceeds with > 99% diastereomeric excess. Intermediate 10 can be readily converted to cyclobutanone derivatives.17, 18... 

Ketene itself and simple alkylketenes are inert towards nonactivated alkenes. F or the preparation of cyclobutanones formally derived from ketene or an alkylketene and nonactivated alkenes, the more reactive dichloroketene or alkylchloroketenes can be used. The corresponding a,a-dichloro- or oc-chlorocyclobutanones can readily be dechlorinated by treatment with zinc in acetic acid, or tributyltin hydride in near quantitative yields. F or example cycloaddition of substituted cyclohexene to dichloroketene gave dichlorocyclobutanone 1 which was dechlorinated to 2 with zinc.13,18 Likewise cycloaddition of cycloalkcnes to chloro(methyl)ketene gave 3 which was dechlorinated to 4.14... 

Although limited by formation of isomeric mixtures, this method represents the only method for the preparation of simple 2- and 3-silyl- and gcrmyl-substituted cyclobutanones. The [2 + 2] cycloadditions of silyl- and germylketenes with alkenes do not take place readily. 

Photolysis of pentacarbonylcarbenechromium complexes produce species that react as if they were ketenes. although no evidence for the generation of free ketenes has been observed. Indeed, photolysis of chromium (alkoxy) carbenes in the presence of a range of simple alkenes produced cyclobutanones 1 in good to very good yield.8,9... 

The use of alkenes with chiral auxiliary groups leads to chiral cyclobutanones 4. Reaction yields of 50 67% and diastereomeric excesses of 86-97% were obtained for the 3-amidocy-clobutanones which were obtained from cycloaddition of the chromium carbene complexes with chiral ene carbamates (see also Section 1.3.4.3.3.).11... 

The advantage of using the photocycloaddition of pentacarbonylcarbenechromium complexes over the ketene cycloaddition method is the absence of ketene dimerization and the avoidance of use of excess alkene in the former method. Also, the mild reaction conditions associated with the use of chromium carbene complexes avoids epimerization and thermodynamic equilibration of 2-monosubstituted cyclobutanones. 

Thermal decomposition of y-lactone tosylhydrazone sodium salts are reported to yield cyclobu-tanones, which can be accounted for by rearrangement of an intermediate oxycarbene. In this manner, the sodium salts of dihydrofuran-2(37/)-one tosylhydrazones 1 were decomposed as a loose powder, at 310 C in a bulb-to-bulb distillation apparatus at an initial pressure of 0.1 Torr, to give the corresponding cyclobutanones 2 in addition to enol ethers, cyclopropanes and open-chain alkenes. Condensable products (74-76%) were collected at — 78 °C, weighed and the ratio of components was determined from their relative GC peak areas.63... 

Moreover, since the cyclobutanones are very often made from the dichloroketene adducts to alkenes, it is noteworthy that Grignard reactions of a,a-dichlorocyclobutanones, such as 7,7-dichlorobicyclo[3.2.0]heptan-6-one with allyhnagnesium bromide, give cyciobutanois, i.e. 6-ai-lyl-7,7-dichlorobicyclo[3.2.0]heptan-6-ol (3) with an exojendo ratio of ca. 10 1 and with no interference of the two chloro-substituents on the high yields.64 However, addition of smaller alkyl groups such as ethylmagnesium bromide resulted in a decrease in the exojendo ratio to ca. 3.2.64... 

Since cyclobutanones are often produced by dichloroketene addition to an alkene (see Section 1.3.5.1.), a,a-dichlorocyclobutanones are very common intermediates. These can be reduced to the monochlorocyclobutanones (see Section 5.2.1.1.). It was reported249 that the C —Cl dipole has a pronounced effect on the sodium borohydride reduction of these compounds. For example, in the reduction of e ra-7-chloro-7-methylbicyclo[3.2.0]hept-2-en-6-one, the normal preference for an exo-face attack was reversed and the exo-alcohol was the major product exo-7-chlorobicyclo[3.2.0]hept-2-en-exo-6-ol exo-2d and exo-7-chlorobicy-clo[3.2.0]hept-2-en-en /o-6-ol endo-2A were obtained in a 78 22 ratio. On the other hand, when the corresponding endo-chloro ketones were reduced, the C —Cl dipole resulted in exclusive formation of the endo-alcohols endo-2b, c. 

Reaction of an alkene with keteniminium salts resulted in [2 + 2]-cycloaddition reactions (see Section 1.3.5.3). Hydrolysis of the intermediate cyclobutanone iminium salts 3 gave the cy-clobutanone 4.- 12 316 The cyclobutanone iminium salts are usually not isolated since they hydrolyze on aqueous workup. 

In marked contrast to that of cyclobutanes, the cycloreversion of cyclobutanones to ethene and ketene88 is most probably a concerted process.89-94 For example, the fact that the pyrolysis of 2-propylcyclobutanone (13) at 350 °C gives ethene and pent-l-ene in the ratio of 3.8 1 is not easily explained by a diradical mechanism.90 This transformation presumably involves two competing cycloreversion reactions. As expected for a concerted process, the conversion through the less sterically congested transition structure is favored. For this reason, ethene is generated as the major alkene.90... 

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