By the Cope rearrangement

Cycloheptadiene (340) is obtained by the Cope rearrangement of cis-divinylcyclopropane (339.) Based on this reaction, highly diastereoselective and enantioselective construction of the 1,4-cycloheptadiene 343 (98% ee) was achieved by domino asymmetric cyclopropanation to generate cA-divinylcyclopropane... 

Bridged bicyclic ketones 7 are obtained by the Cope rearrangement of silyl enol ethers or lithium enolate anions derived from ent/o-vinylcyclopropanes 4. i 11 The corresponding exo-isomers of 5 require flash-vacuum pyrolysis at temperatures in the range of 250-500°C to... 

Novel spirocyclic compounds have been prepared by the Cope rearrangement of taxane-like tricyclic compounds having a 1,5-diene moiety. The transformation was found to be reversible and the product distribution was found to be greatly dependent on the solvent polarity. The intramolecular cyclopropanation of dienylmethyl vinyldiazoacetate, followed by a Cope rearrangement, has been used in the... 

We will ultimately end up drawing both processes, and it does not matter the order in which we draw these two processes. Below, the Claisen rearrangement is drawn first, followed by the Cope rearrangement. If instead, the Cope rearrangement was drawn first, followed by the Claisen rearrangement, the same product would be obtained. 

The most intriguing hydrocarbon of this molecular formula is named buUvalene, which is found in the mixture of products of the reaction given above. G. SchrOder (1963, 1964, 1967) synthesized it by a thermal dimerization presumably via diradicais of cyciooctatetraene and the photolytical cleavage of a benzene molecule from this dimer. The carbon-carbon bonds of buUvalene fluctuate extremely fast by thermal Cope rearrangements. 101/3 = 1,209,6(X) different combinations of the carbon atoms are possible. 

The most important sigmatropic rearrangements from the synthetic point of view are the [3,3] processes involving carbon-carbon bonds. The thermal rearrangement of 1,5-dienes by [3,3] sigmatropy is called the Cope rearrangement. The reaction establishes equilibrium between the two 1,5-dienes and proceeds in the thermodynamically favored direction. The conversion of 24 to 25 provides an example ... 

Like the Cope rearrangement, the Claisen rearrangement is sensitive to substituents on the reacting system. Cyano groups promote the rearrangement by a factor of 10 at positions 2 and 4 and have smaller effects at the other positions, as shown below. Data are also available for methoxy groups at positions 2, 4, 5, and 6. ... 

If both ortho positions bear substituents other than hydrogen, the allyl group will further migrate to the para position. This reaction is called the para-Claisen rearrangement. The formation of the para-substituted phenol can be explained by an initial Claisen rearrangement to an ortho-2l y intermediate which cannot tautomerize to an aromatic o-allylphenol, followed by a Cope rearrangement to the p-allyl intermediate which can tautomerize to the p-allylphenol e.g. 6 ... 

At 75 C, 2-phenyl-l,3-oxazepine undergoes a [27r + 47t] cycloaddition to 2,5-dimethyl-3,4-diphenylcyclopentadienone to give 3, which at 120 C is transformed into the isomer 4 by a Cope rearrangement.16... 

Electronically rich 1,3-butadienes such as Danishefsky s diene react with chromium alkenylcarbene complexes affording seven-membered rings in a formal [4S+3C] cycloaddition process [73a, 95a]. It is important to remark on the role played by the metal in this reaction as the analogous tungsten carbene complexes lead to [4S+2C] cycloadducts (see Sect. 2.9.1.1). Formation of the seven-membered ring is explained by an initial cyclopropanation of the most electron-rich double bond of the diene followed by a Cope rearrangement of the formed divinylcyclopropane (Scheme 65). Amino-substituted 1,3-butadienes also react with chromium alkenylcarbene complexes to produce the corre-... 

The predictions of the reactivities by the geminal bond participation have been confirmed by the bond model analysis [103-105] of the transition states and the calculations of the enthalpies of activation AH of the Diels-Alder reaction [94], the Cope rearrangement [95], the sigmatropic rearrangement [96], the Alder ene reaction [100], and the aldol reaction [101] as are illustrated by the reactions of the methyl silyl derivatives in Scheme 38 [102], The bond is more electron donating than the bond. A silyl group at the Z-position enhances the reactivity. 

In contrast to the synthesis of carbocyclic rings, the Cope rearrangement has been used sparsely for generating azepinones. Recently, the enantioselectivity of the conversion of 2-aza-divinylcyclopropane 286 has been investigated. The synthesis started from the optically active cyclopropanecarboxylic acid (90% ee), which had been converted into the isocyanate 286 by initial azidation to 285 and a consecutive Curtius rearrangement. Furthermore, the conditions of the iso-... 

Entry 2 illustrates the reversibility of the Cope rearrangement. In this case, the equilibrium is closely balanced with the reactant benefiting from a more-substituted double bond, whereas the product is stabilized by conjugation. The reaction in Entry 3 involves a cz s-divinylcyclopropane and proceeds at much lower temperature that the previous examples. The reaction was used in the preparation of an intermediate for the synthesis of pseudoguiane-type natural products. 

Trifluoromethyl imidates show similar reactivity.262 Imidate rearrangements are catalyzed by palladium salts.263 The mechanism is presumably similar to that for the Cope rearrangement (see p. 555). 

The 2-azonia analog of the Cope rearrangement is estimated to be accelerated by 106, relative to the unsubstituted system.270 The product of the rearrangement is an isomeric iminium ion, which is a mild electrophile. In synthetic applications, the reaction is often designed to generate this electrophilic site in a position that can lead to a cyclization by reaction with a nucleophilic site. For example, the presence of a 4-hydroxy substituent generates an enol that can react with the iminiun ion intermediate to form a five-membered ring.271... 

Even if full potential energy surfaces are not calculated, simple EHT calculations, skilfully coupled with orbital symmetry considerations, can provide insight into complex reactivity problems. This is well exemplified by Hoffmann and Stohrer s analysis of substituent effects on the Cope rearrangement (28). 

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