Cycloalkenes cyclopentene

Alternatively, paraformaldehyde [39] or aqueous methyl formate has been suggested as non-gaseous sources for the generation of syngas (Scheme 1.35) [39,40]. A catalyst prepared by the reaction of Ru3(CO)j 2 and tricyclohexylphos-phine is able to decarbonylate methyl formate and assist in the subsequent water gas shift (WGS) reaction. Finally, the mixture of CO and H2 formed can react with the olefin. In this manner, several cycloalkenes (cyclopentene. 

When the halogenation reaction is carried out on a cycloalkene, such as cyclopentene, only the trews stereoisomer of the dihalide addition product is formed rather than the mixture of cis and trans isomers that might have been expected if a planar carbocation intermediate were involved. We say that the reaction occurs with anti stereochemistry, meaning that the two bromine atoms come from opposite faces of the double bond—one from the top face and one from the bottom face. 

Dall Asta and Motroni (44, 57) provided direct experimental evidence for the transalkylidenation mechanism in the case of cycloalkenes. With a catalyst system consisting of WOCI4, C2H6A1C12, and benzoyl peroxide they prepared a random copolymer of cyclooctene and cyclopentene, the cyclo-pentene double bond being labeled with 14C. The distribution of the radioactivity in the copolymer formed will depend on the site of ring opening. 

By analogy with the intramolecular insertion of phenylthiocarbenes, the reaction of (oo-oxido)diazoalkanes 93 resulted in the formation of cycloalkenes 94.38 However, the reaction was proven to proceed not via a carbene route b but a nitrene route a as shown in Scheme 26. The nitrene route is supported by the formation of heterocyclic products 98 and 99.39 This insertion reaction was used in the cydization step to the cyclopentene ring formation of isocarbacycline 97.40... 

The optimized protocol has also been applied to a wide range of open-chain and cyclic dienes (for selected examples, see Table 11.11) [113], The latter generally give higher yields than non-terminal alkenes and cycloalkenes, except for strained ones such as JV-benzyl-pyrroline, cyclopentene, and norbornene (Table 11.10, entries 20—22). 

A systematic study has confirmed the low activity of EHs toward cycloalkene oxides (1,2-epoxycycloalkanes, 10.123) [184], In the presence of mouse liver microsomal EH, activity was very low for cyclopentene oxide and cyclohexene oxide (10.123, n = 1 and 2, respectively), highest for cyclo-heptene oxide (10.123, n = 3), and decreased sharply for cyclooctene oxide (10.123, n = 4) and higher homologues. Mouse liver cytosolic EH showed a different structure-activity relationship in that the highest activity involved cyclodecene oxide (10.123, n = 6). With the exception of cyclohexene oxide, which exhibited an IC50 value toward microsomal EH in the p.M range, cycloalkene oxides were also very weak inhibitors of both microsomal and cytosolic EH. 

Cycloalkenes such as cyclohexene, 1-methylcyclohexene, cyclopentene, and nor-bornene are hydrosilylated with triethylsilane in the presence of aluminum chloride catalyst in methylene chloride at 0 °C or below to afford the corresponding hydrosilylated (triethylsilyl)cycloalkanes in 65-82% yields [Eq. (23)]. The reaction of 1-methylcyclohexene with triethylsilane at —20 °C occurs regio- and stereoselectively to give c/i-l-triethylsilyl-2-methylcyclohexane via a tra x-hydrosilylation pathway. Cycloalkenes having an alkyl group at the double-bonded carbon are more reactive than non-substituted compounds in Lewis acid-catalyzed hydrosilylations. ... 

Hoveyda et al. reported a novel method for synthesizing of chromene 71 by ROM-RCM of cycloalkene 70 bearing the phenyl ether at the 3-position [Eq. (6.48)]." ° The yield is improved when the reaction is carried out under ethylene gas. In the case of cyclopentene 70a (n = 0) or cyclohexene 70b (n = 1), the yield is poor because the starting cycloalkene is in a state of equihbrium with the product and a thermodynamic product should be formed under these reaction conditions. They obtained enantiomeric ally pure cycloheptene derivative (5)-70e using zirconium-catalyzed kinetic resolution of 70e developed by their group, and chromene 71c was synthesized as a chiral form via ROM-RCM using lb [Eq. (6.49)] ... 

As expected, the metathesis polymerization of more strained cycloalkenes, such as cyclobutene, occurs more rapidly than less strained structures such as cyclopentene. 

Polymers containing rings incorporated into the main chain (e.g., by double-bond polymerization of a cycloalkene) are also capable of exhibiting stereoisomerism. Such polymers possess two stereocenters—the two atoms at which the polymer chain enters and leaves each ring. Thus the polymerization of cyclopentene to polycyclopentene [IUPAC poly(cyclopen-tane-l,2-diyl)] is considered in the same manner as that of a 1,2-disubstituted ethylene. The... 

This means that, formally, the cyclopentene ring in 65b is cleaved and two carbon-carbon bonds are formed between the double and triple bonds, respectively, to produce 66b (Figure 6). Ring size of the cycloalkene formed in this reaction corresponds to the carbon number of the original cycloalkene plus two carbons. 

Among the cycloalkenes, cyclobutene, cyclopropene and cylcohexene are most common. Cyclobutene is about 4 kcal/mol more strained than cyclopentene. The smaller bond angles mean more deviation from 120°, and this makes cyclobutene more reactive than cyclopentene. 

When cyclopentene reacts with Br2, the product is a racemic mixture of 1,2-dihromocyclopentane. Addition of Bt2 to cycloalkenes gives a cyclic hromonium ion intermediate instead of the planar carhocation. The reaction is stereospecific, and gives only anti addition of dihalides. 

A cationic mechanism is responsible for the ring contraction of cycloalkenes with thallium(III) salts in the presence of diluted perchloric acid resulting in the formation of formylcycloalkanes. This method was unsuccessful for cyclopentene, whereas 1-methylcyclopentene gave acetyicy-clobutane (32) in 16-24% yield98 depending on the better stabilization of the intermediate cationic species. 

The present method utilizes commercially available cycloalkenes and proceeds under mild conditions to provide synthetically useful products. The method was shown to be general in the series of cycloalkenes investigated. Yields range from moderate (cyclopentene) to excellent (higher homologues). 

The acid-catalyzed isomerization of cycloalkenes usually involves skeletal rearrangement if strong acids are used. The conditions and the catalysts are very similar to those for the isomerization of acyclic alkenes. Many alkylcyclohexenes undergo reversible isomerization to alkylcyclopentenes. In some cases the isomerization consists of shift of the double bond without ring contraction. Side reactions, in this case, involve hydrogen transfer (disproportionation) to yield cycloalkanes and aromatics. In the presence of activated alumina cyclohexene is converted to a mixture of 1-methyl- and 3-methyl-1-cyclopentene 103... 

Whereas only limited stereoselectivity is characteristic of the metathesis of acyclic olefins, ring-opening metathesis polymerization of cycloalkenes may be highly stereoselective provided the proper catalysts and reaction conditions are selected. Cyclopentene, for instance, is transformed to either all-cis [Eq. (12.25)] or all-frans polypentenamers [Eq. (12.26)] in the presence of tungsten catalysts 21 92... 

Effect of structure of cycloalkenes on the individual rates of hydrogenation (relative to cyclopentene) on metal catalysts compared to diimide reductions. 

The C—C=C angle in alkenes normally is about 122°, which is 10° larger than the normal C—C—C angle in cycloalkanes. This means that we would expect about 20° more angle strain in small-ring cycloalkenes than in the cycloalkanes with the same numbers of carbons in the ring. Comparison of the data for cycloalkenes in Table 12-5 and for cycloalkanes in Table 12-3 reveals that this expectation is realized for cyclopropene, but is less conspicuous for cyclobutene and cyclopentene. The reason for this is not clear, but may be connected in part with the C-H bond strengths (see Section 12-4B). 

The catalytic properties of Del-Ti-MWW have been compared with those of other titanosilicates in the epoxidation of cyclic alkenes (Table 4.4). The TON decreased sharply for TS-1, Ti-beta and 3D Ti-MWW with increasing molecular size of cyclic alkenes. Ti-MCM-41 with mesopores, however, showed higher TONs for cyclooctene and cyclododecene. This implies that the reaction space is extremely important for the reactions of bulky molecules. The delamination of Ti-MWW increased the TON greatly for not only cyclopentene but also bulkier cycloalkenes. Especially, the catalytic activity of Del-Ti-MWW was about 6 x higher than that of Ti-MWW for cyclooctene and cyclododecene. Del-Ti-MWW even turned out to be superior to Ti-MCM-41 in the epoxidation of bulky substrates. This should be due to the high accessibility of Ti active sites in Del-Ti-MWW. Thus the delamination was able to change Ti-MWW into an effective catalyst applicable to reactions of bulky substrates. 

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