Cyclopropanes, from carbene additions alkenes

Carbene addition occurs in a syn fashion from either side of the planar double bond. The relative position of substituents in the alkene reactant is retained in the cyclopropane product. Carbene addition is thus a stereospecific reaction, since cis and trans alkenes yield different stereoisomers as products, as illustrated in Sample Problem 26.4. 

Among the methods at hand to synthesize cyclopropane derivatives, carbene addition to alkenes plays a prominent role 63). As a source of vinylcarbenes, cyclopropenes might be useful in this kind of approach. In 1963, Stechl was the first to observe a transition metal catalyzed cyclopropene-vinylcarbene rearrangement64). When treating 1,3,3-trimethylcyclopropene with copper salts, dimerization occurred to give 2,3,6,7-tetramethyl-octa-2,4,6-triene (9), the product from a formal recombination of the corresponding vinylcarbene (Eq. 8). 

By application of the Simmons-Smith reaction it is possible to synthesize a cyclopropane from an alkene by formal addition of carbene to the carbon-carbon double bond, without a free carbene being present in the reaction mixture the... 

From the point of view of both synthetic and mechanistic interest, much attention has been focused on the addition reaction between carbenes and alkenes to give cyclopropanes. Characterization of the reactivity of substituted carbenes in addition reactions has emphasized stereochemistry and selectivity. The reactivities of singlet and triplet states are expected to be different. The triplet state is a diradical, and would be expected to exhibit a selectivity similar to free radicals and other species with unpaired electrons. The singlet state, with its unfilled p orbital, should be electrophilic and exhibit reactivity patterns similar to other electrophiles. Moreover, a triplet addition... 

Photoelimination of nitrogen from diazirines, for example, proceeds via carbene intermediates. 3-tert-Butyldiazirine (395) is converted into the cyclopropane 396 and the alkene 397 with the formation of the carbene insertion product being favored from the singlet state.328 3-Cyclopropyl-3-chlorodiazirine (398) has similarly been converted to the carbene 399 which undergoes both rearrangement to l-chlorocyclobutene(400)329 and addition... 

Calculations [28] on the formation of cyclopropanes from electrophilic Fischer-type carbene complexes and alkenes suggest that this reaction does not generally proceed via metallacyclobutane intermediates. The least-energy pathway for this process starts with electrophilic addition of the carbene carbon atom to the alkene (Figure 1.9). Ring closure occurs by electrophilic attack of the second carbon atom... 

Ab initio and RRKM calculations indicate that the reactions of C, CH, and (H2C ) with acetylene occur with no barrier." Laser flash photolysis of the cyclopropanes (69) and (70) was used to generate the corresponding dihalocarbenes. The absolute rate constant for the formation of a pyridine ylide from Br2C was (4-11) x 10 lmoP s. The rates of additions of these carbenes to alkenes were measured by competition with pyridine ylide formation and the reactivity of BrClC was found to resemble that of Br2C rather than CI2C . 

Insight into the nature of the intermediate in the cyclopropanation of electron-rich and electron-poor alkenes was given by laser flash photolysis (LFP) studies of phenyl-bromodiazirine in the presence of various amounts of tetrabutylammonium bromide.23 Electron-rich alkenes react exclusively with the carbene (11) leading to (12). Electron-poor alkenes yield cyclopropanes (13) only slowly with the carbene (11) and more rapidly with the carbanion (14) arising from the addition of the bromide to the carbene. 

Addition of chloro(phenyl)carbene, generated from diazirine, to alkenes is stereospecific, yet diethyl (Z)-but-2-enedioate isomerized partially to give a mixture of stereoisomeric cyclopropanes(for a more detailed discussion see Houben-Weyl, Vol. E19b, p995). 

Generation of chloro(2-furyl)carbene and chloro(2-thienyl)carbene from 2-dichloromethyl-furans 1 or 2-diehloromethylthiophenes 2 and a base, followed by addition to an alkene, gave l-chloro-l-(2-furyl)- or l-(2-thienyl)cyclopropanes, respectively "(for earlier work, see Houben-Weyl, Vol. E19b, p 1001). The reactions were carried out using potassium /crt-butoxide as the base with, or without, 18-crown-6, or solid potassium hydroxide and a catalytic amount of benzyltriethylammonium chloride (TEBAC) (solid-liquid variant of a phase-transfer catalytic system ). Under both conditions, yields of cyclopropanes were usually good, yet the phase-transfer catalytic system seems to be more convenient from a practical point of view. Addition of the above described carbenes to alkenes was stereospecific. 

Until the last decade, product studies formed the main evidence for carbene formation singlet carbenes formed cyclopropanes from alkenes stereospecifically, while triplet carbenes formed cyclopropanes non-stereospecifically. Formation of a cyclopropane (though not by addition to an alkene) via a carbocation route was demonstrated and, more recently, it has been shown that p values for insertion-addition selectivity and for cyclopropanation stereoselectivity vary as to photochemical or thermal generation of the carbene. The authors of this latter study suggest that a ground state diazo compound could be masquerading as a carbene in its thermal reaction with olefins, possibly by electrocyclic... 

Method using Base and a Substituted Halogenomethane. The influence of catalyst anions (as their tetrabutylammonium salts) and cations (as chlorides or bromides) on the generation of dichlorocarbene from chloroform-sodium hydroxide has been studied under standard conditions by determining the yield of dichloronorcarane produced from the addition of the carbene to cyclohexene. The presence of olefin appears to be necessary since in its absence only very slow decomposition of the trichloromethyl anion occurs. Dehmlow has also devised a new procedure for phase-transfer-catalysed cyclopropanation. Treatment of an alkene (or cycloalkene) with sodium trichloroacetate and a tetra-alkylammonium salt in chloroform without... 

The mononuclear complex 13 was also employed for carbene transfer reactions from ethyl diazoacetate (EDA) in a range of reactions that led to the alkenation of aldehydes, cyclopropanation, and carbene insertion into N—H and O—H bonds [32]. The complex proved particularly adept at the last process, especially aromatic amines and aliphatic alcohols. Addition of the PIN ligand (l-isopropyl-3-(5,7-dimethyl-l,8-naphthyrid-2-yl)imidazol-2-ylidene) to [Ru2(CO)4(OAc)2], foUowed by treatment with Na[BAr 4] gave the dinuclear complex [Ru2(PIN)2(CO)4][[BAr 4] 2, which showed some improved reactivity compared to 13, particularly in the transfer of CH(C02Et) to aldehydes [109]. 

The Puddephatt-Tipper team " have shown that reductive elimination involving the formation of cyclopropanes from platinacyclopropanes appears to involve a concerted process rather than the production of carbene-alkene intermediates (as does also the oxidative addition involving the reverse reaction, and the skeletal isomerization of platinacyclopropanes). They " have also proposed a similar concerted behavior for a reaction which could be looked upon either as a reductive elimination or a substitution, namely, the overall process in equation (46). 

Alkenes are reduced by addition of H2 in the presence of a catalyst such as platinum or palladium to yield alkanes, a process called catalytic hydrogenation. Alkenes are also oxidized by reaction with a peroxyacid to give epoxides, which can be converted into trans-l,2-diols by acid-catalyzed hydrolysis. The corresponding cis-l,2-diols can be made directly from alkenes by hydroxylation with OSO4. Alkenes can also be cleaved to produce carbonyl compounds by reaction with ozone, followed by reduction with zinc metal. In addition, alkenes react with divalent substances called carbenes, R2C , to give cyclopropanes. Nonhalo-genated cyclopropanes are best prepared by treatment of the alkene with CH2I2 and zinc-copper, a process called the Simmons-Smith reaction. 

Cyclopropanations of alkenes with alkyl diazoacetates are catalysed by rhodium(ii) carboxylates, and Sasaki et al have shown that crown ethers have several advantages over quaternary ammoniurq ions for the catalytic synthesis of allene-cyclopropanes from addition of allene-carbenes to olehnic substrates. 

The addition of dichlorocarbene, generated from chloroform, to alkenes is a useful synthesis of cyclopropanes. The procedures based on lithiated halogen compounds have been less generally used in synthesis. Section D of Scheme 10.6 gives a few examples of addition reactions of carbenes generated by a elimination. 

In Summary Diazomethane is a useful synthetic intermediate as a methylene source for forming cyclopropanes from alkenes. Halogenated carbenes, which are formed by dehydro-halogenation of halomethanes, and the Simmons-Smith reagent, a carbenoid arising from the reaction of diiodomethane with zinc, also convert alkenes into cyclopropanes. Additions of carbenes to alkenes differ from other addition processes because a single carbon atom becomes bonded to both alkene carbons. 

Addition reactions with alkenes to form cyclopropanes are the most studied reactions of carbenes, both from the point of view of understanding mechanisms and for synthetic applications. A concerted mechanism is possible for singlet carbenes. As a result, the stereochemistry present in the alkene is retained in the cyclopropane. With triplet carbenes, an intermediate 1,3-diradical is involved. Closure to cyclopropane requires spin inversion. The rate of spin inversion is slow relative to rotation about single bonds, so mixtures of the two possible stereoisomers are obtained from either alkene stereoisomer. 

Additional evidence for a second intermediate in supposed carbene reactions comes from numerous studies.17-29 In the earliest experimental approach, the carbene precursor, frequently a diazirine, was photolyzed in the presence of increasing quantities of an alkene, which trapped the carbene with the formation of a cyclopropane (5 in Scheme 1). If carbene 2 were the sole product-forming intermediate, as depicted in Scheme 1, then the ratio of its alkene addition product (5) to its 1,2-H shift rearrangement product (4) would vary linearly with alkene concentration Eq. 9. 

The generation of the dichloromethane under phase-transfer conditions may be facilitated by the addition of a trace of ethanol. Alkoxide anions, generated under the basic conditions, are more readily transferred across the two-phase interface than are hydroxide ions (see Chapter 1). Although this process may result in the increased solvolysis of the chloroform, it also produces a higher concentration of the carbene in the organic phase and thereby increases the rate of formation of the cyclopropane derivatives from reactive alkenes. 

Not much is known about the reactivity of the phosphinocarbene 2i. Problems arise, at least in part, from the high 1,3-dipolar reactivity of the diazo precursor li, which hides any carbene reactivity. Indeed, although li is stable in a toluene solution at 60°C for hours, the addition of an electron-poor olefin, such as a perfluoroalkyl-monosubstituted alkene, induces the exclusive formation of the thermodynamically more stable anti-isomer of the cyclopropane 14 (see Section V,B,3,a).36 This clearly demonstrates that the cyclopropanation reaction does not involve the carbene 2i, but that an initial [2 + 3]-cycloaddition occurs leading to the pyrazoline 13, which subsequently undergoes a classical N2 elimination.37... 

This dominance of sulfur in the reactions with electrophiles is well brought out in the addition of carbenes to the-two monocycles. Tire allylic sulfide (5,6-dihydro-2jF/- thiopyran) only affords the products of reaction at sulfur, while the vinylic sulfide (3,4-dihydro-2f/-thiopyran), in which the alkene is a little more nucleophilic due to the small interaction with the heteroatom, shows dichotomous behaviour. Dichlorocarbene affords the cyclopropane product (78) in 70% yield, but the stabilized ylide (76) is produced from bismethoxycar-bonylmethylide and (75). In fact it is possible that the initial reaction with dichlorocarbene is reaction at sulfur and subsequent rearrangement of this less stabilized ylide. Schemes 6 and 7 illustrate the results and proposed mechanisms (77JOC3365,64JOC2211). 

Cyclopropane formation occurs from reactions between diazo compounds and alkenes, catalyzed by a wide variety of transition-metal compounds [7-9], that involve the addition of a carbene entity to a C-C double bond. This transformation is stereospecific and generally occurs with electron-rich alkenes, including substituted olefins, dienes, and vinyl ethers, but not a,(J-unsaturated carbonyl compounds or nitriles [23,24], Relative reactivities portray a highly electrophilic intermediate and an early transition state for cyclopropanation reactions [15,25], accounting in part for the relative difficulty in controlling selectivity. For intermolecular reactions, the formation of geometrical isomers, regioisomers from reactions with dienes, and enantiomers must all be taken into account. 

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