Alkene derivatives cyclopropane derivative formation

From this compound as well as from other alkylcyclohexanes the yield of ring-opening products is relatively small, about = 0.1-0.4, and G = 0.3-1.6 [108,110] (Table 6), while usually the main decomposition process is the hydrogen formation, which leaves the cyclic structure intact. Here, and with the other alkylcyclohexanes and alkylcyclopentanes, the scission of the ring to smaller molecular mass alkenes and cyclopropane derivates was detected with very low yield. 

Diazomethane is also decomposed by N O)40 -43 and Pd(0) complexes43 . Electron-poor alkenes such as methyl acrylate are cyclopropanated efficiently with Ni(0) catalysts, whereas with Pd(0) yields were much lower (Scheme 1)43). Cyclopropanes derived from styrene, cyclohexene or 1-hexene were formed only in trace yields. In the uncatalyzed reaction between diazomethane and methyl acrylate, methyl 2-pyrazoline-3-carboxylate and methyl crotonate are formed competitively, but the yield of the latter can be largely reduced by adding an appropriate amount of catalyst. It has been verified that cyclopropane formation does not result from metal-catalyzed ring contraction of the 2-pyrazoline, Instead, a nickel(0)-carbene complex is assumed to be involved in the direct cyclopropanation of the olefin. The preference of such an intermediate for an electron-poor alkene is in agreement with the view that nickel carbenoids are nucleophilic 44). 

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. 

In qualitative terms, the rearrangement reaction is considerably more efficient for the oxime acetate 107b than for the oxime ether 107a. As a result, the photochemical reactivity of the oxime acetates 109 and 110 was probed. Irradiation of 109 for 3 hr, under the same conditions used for 107, affords the cyclopropane 111 (25%) as a 1 2 mixture of Z.E isomers. Likewise, DCA-sensitized irradiation of 110 for 1 hr yields the cyclopropane derivative 112 (16%) and the dihydroisoxazole 113 (18%). It is unclear at this point how 113 arises in the SET-sensitized reaction of 110. However, this cyclization process is similar to that observed in our studies of the DCA-sensitized reaction of the 7,8-unsaturated oximes 114, which affords the 5,6-dihydro-4//-l,2-oxazines 115 [68]. A possible mechanism to justify the formation of 113 could involve intramolecular electrophilic addition to the alkene unit in 116 of the oxygen from the oxime localized radical-cation, followed by transfer of an acyl cation to any of the radical-anions present in the reaction medium. 

Elimination reactions of this type can be useful in synthesis for the formation of carbon-carbon bonds. For example, if dibromocarbene is generated in the presence of an alkene, it will react by cycloaddition to give a cyclopropane derivative ... 

The formation of cyclopropane derivatives by photolysis of diazoalkanes in the presence of alkenes is believed to occur by photolytic decomposition of the diazoalkane to yield the carbene, followed by addition of this carbene to the alkene. Cycloaddition of this type has been reported in furan, dihydrofuran, and thiophene.198 Thus, photolysis of ethyl diazoacetate in thiophene yields the bicyclic sulfur heterocycle (215). Alternatively, photolysis of 3-diazo-l-methyl-oxindole (216) in cyclohexene leads to the formation of two isomers which are thought to have the spirocyclopropyl structure (217) photolysis in ethanol yields 3-ethoxy-1-methyloxindole.194... 

The mechanism for the formation of this carbenoid and for its reaction with alkenes need not concern us here. Just remember that it reacts as though it is methylene. The Simmons-Smith reaction is an excellent way to prepare cyclopropane derivatives from alkenes, as shown in the following examples. Note the stereochemistry in the second equation. 

Interaction of 4,5 6,7-di-0-cyclohexylidene-2,3-dideoxy-l-C-phe-nyl-L-arafeino-hept-2-enose (65) with phenylmethylenetriphenylphos-phorane was accompanied9 6 by the formation of triphenylphosphine, instead of the expected triphenylphosphine oxide, thus indicating the abnormal character of this reaction. This result may be interpreted as involving possible addition of the phosphonium ylide to the alkenic bond, with subsequent stabilization of the intermediate betaine 82 through elimination of triphenylphosphine, and closure of the three-membered ring2(f) with formation of the cyclopropane derivative 83, as shown in equation 5. 

R and R may be H, methyl, cyclopropyl, cyano, or ester groups. The phenylcarbene formed on irradiation of trans-l,2-diphenyloxirane has been trapped and identified in the form of a cyclopropane derivative in methanol in the presence of benzyl methyl ether and alkenes. Photolysis in the presence of 2,3-dimethyl-2-butene proceeds by cycloaddition with the formation of cyclopropane-carboxylic acid and oxetane derivatives (Eq. 368). ... 

Cyclopropane derivatives have been prepared similarly from dibromo compounds, Br2CXCOOR, where X is another electron-withdrawing group, and conjugated alkenes, R CH=CHY (Y = electron-withdrawing group), in the presence of tributylstibine and again formation of a stibonium salt as an intermediate is postulated (equation 51) . ... 

The ion (19) plays an important role in the formatiotl of e-tehchene however, the reaction is more complex. In addition to the a- and e-fenchenes, small amounts of cyclofenchene (20), 3-fenchene (23), 7-fenchene (22) and 8-fenchene (21) are also formed. Cyclofenchene (20) represents the key to the formation of these substances (see Scheme 7). It may arise by the loss of a proton from the carb tion (24). Reprotonation of the cyclopropane ring may lead to a new carbocation from which the alkenes may be derived. 

SET Induced Reactions - Further studies on ring opening reactions of 1,2-diarylcyclopropanes have focused on compounds (83) bearing an acetyl functional group.All of the cyclopropane derivatives studied show efficient cis.trans isomerism with reasonable quantum efficiency. The isomerism reaction involves an acetophenone-like triplet state with lifetimes shorter than 1 ns. The formation of ring opened products also takes place but inefficiently to give a mixture of the two alkenes (84) and (85). A study of the electron-transfer-induced photochemical reactivity of the cyclopropane (86) has been reported in the co-sensitisation system (biphenyl/phenanthrene/DCA). ... 

Although cyclopropylidenes have been generated by a number of independent methods which include cycloaddition of atomic carbon to alkenes, decarbonylation of cyclo-propylideneketenes, decarboxylation of oxaspiropentanes, from a preparative viewpoint, the a-elimination reaction of cyclopropane derivatives is most practical because of the mild reaction conditions and the availability of the starting materials. These methods are illustrated by the formation of allenes from atomic carbon/alkene reactions in Table 1 and in the preparation of 3/4, and from cyclopropanes in the preparation of 5/6. Examples showing allenes from decarbonylation of cyclopropylideneketenes are shown in the preparations of compounds 7/8, 9, 10, " and 11. ... 

A ruthenium carbene complex in the presence of a chiral ligand is capable of catalyzing the formation of optically active cyclopropane derivatives from alkenes and diazo compounds in high enantiomeric excess [177]. A mixture of [RuCl2(/ -cymene)] in the presence of pybox-(5,5)-/ catalyzes the asymmetric cyclopropanation of styrene (eq (48)). The key intermediate is proposed to be a dichloro(pybox)ruthenium carbene complex. 

The rhodium chemistry just presented actually involves C=Rh species rather than a free carbene. In this section, we will look at a general class of compounds called carbenoids. A carbenoid is a reactive intermediate that reacts similarly to a carbene but does not actually involve formation of a carbene. The most commonly used carbenoid is generated by reaction of diiodomethane and a Zn/Cu couple this reaction, when it adds to alkenes, is called the Simmons-Smith reaction.316 A simple example is the conversion of cyclohexene to bicyclo[4.1.0]heptane (norcarane, 336). Initial reaction of diiodomethane with zinc gave an iodozinc compound (399-see sec. 9.8.B for a brief discussion of organozinc compounds), which added to the alkene to give 400. Loss of zinc iodide (Znl2) gave the cyclopropane derivative (343 in this case).3ll A one-step... 

The reaction system (6-37) includes the thermal azo-extrusion of a cyclic azo compound to a cyclopropane derivative and the direct formation of cyclopropanes, catalyzed by metal complexes. Synthetic routes to cyclopropane derivatives became an important subject in the last two decades, and one frequently used method is the 1,3-dipolar cycloaddition of a diazoalkane to an alkene followed by thermal or photolytic azo-extrusion of the 4,5-dihydro-3//-pyrazole formed to the cyclopropane derivative (6-37 A). This route can be followed in many cases without isolation, or even without direct observation, of the 4,5-dihydro-3//-pyrazole. Therefore, it is formally very similar to cyclopropane formation from alkenes with diazoalkanes, in which a carbene is first formed by azo-extrusion of the diazoalkane (see Sect. 8.3). As shown in pathway (6-37 B), this step can be catalyzed by copper, palladium, or rhodium complexes (see Sects. 8.2, 8.7, and 8.8). There are cases where it is not clearly known whether route A or B is followed. Scheme 6-37 also includes... 

A general mechanistic problem exists with alkylcarbenes because they are often difficult to detect as metastable intermediates due to intramolecular insertion. In the case of l-(bicyclo[2.2.1]-heptyl)diazomethane (1-norbornyldiazomethane), Bian and Jones (1993) showed that the formation of the carbene can be demonstrated by the stereospecific addition to alkenes, leading to the corresponding cyclopropane derivatives. The stereospecificity is, of course, evidence for trapping the singlet. It is not known yet whether this method has general applicability. 

Stereochemical data support the occurence of these intermediates, as also shown by Doyle et al. (1984 b) They compared reactivities and stereoselectivities of cyclopropanations of phenyldiazomethane and eleven different open-chain alkenes containing a terminal double bond or a double bond in the chain, and a cyclic alkene (cyclopentene) catalyzed by the binuclear complex Rh2(OCOCH3)4 (8.127, see later in this section), with the reactivities and stereoselectivities of cyclopropanations of the same alkenes with (benzylidene)(pentacarbonyl)tungsten [(CO)5W(CHC6H5)], i.e., a stable metal-carbene. An almost perfect linear relationship of the cyclopropane derivatives of the eleven alkenes with the two carbene sources was obtained. On this basis, Doyle and his coworkers concluded that the reaction starts with an initial association of the alkene 71-bond with the electrophilic center of the metal-carbene complex, followed by o-bond formation with backside displacement... 

D.i.a. Formation of Cyclopropane Derivatives by Two Successive Intramolecular Carbopalladations. Intramolecular carbopalladation starting from 1,( —l)-dienes with a suitable leaving group at the 2-position and a substituent at the (n-l)-position of the alkene terminator leads to a neopentylpalladium intermediate, which can only continue the cascade by a 3-eJto-tng-carbopalladation to eventually form bicyclo[(n—2). 1.0]alkenes. This sequence works equally well for ring sizes five, six, and seven in the first formed ring (Scheme 22) and even heterocyclic systems can be constructed by this mode (Scheme 22). 

Deprotonation of TosyIhyd razones. The deprotonation of to-sylhydrazones with LHMDS provides the corresponding lithium salts, which can be further decomposed into the diazo intermediates. The addition of late transition metal complexes leads to the formation of metal carbenoid species which undergo various reactions, such as cyclopropanation, aziridination, epoxidation, and C-H insertion. For instance, the lithium salt of tosylhydrazone 2, prepared from LHMDS, is reacted with an imine or an alkene in the presence of rhodium(II) acetate and a chiral sulfide to give respectively, the corresponding aziridine or cyclopropane derivatives (eqs 36 and 37). Under similar reaction conditions, the sodium salt prepared from NHMDS works equally well. 

---