Olefin system Diels-Alder reaction

Harano and colleagues [48] found that the reactivity of the Diels-Alder reaction of cyclopentadienones with unactivated olefins is enhanced in phenolic solvents. Scheme 6.28 gives some examples of the cycloadditions of 2,5-bis-(methoxycar-bonyl)-3,4-diphenylcyclopentadienone 45 with styrene and cyclohexene in p-chlorophenol (PCP). Notice the result of the cycloaddition of cyclohexene which is known to be a very unreactive dienophile in PCP at 80 °C the reaction works, while no Diels-Alder adduct was obtained in benzene. PCP also favors the decarbonylation of the adduct, generating a new conjugated dienic system, and therefore a subsequent Diels-Alder reaction is possible. Thus, the thermolysis at 170 °C for 10 h of Diels-Alder adduct 47, which comes from the cycloaddition of 45 with 1,5-octadiene 46 (Scheme 6.29), gives the multiple Diels-Alder adduct 49 via decarbonylated adduct 48. In PCP, the reaction occurs at a temperature about 50 °C lower than when performed without solvent, and product 49 is obtained by a one-pot procedure in good yield. 

This reviews contends that, throughout the known examples of facial selections, from classical to recently discovered ones, a key role is played by the unsymmetri-zation of the orbital phase environments of n reaction centers arising from first-order perturbation, that is, the unsymmetrization of the orbital phase environment of the relevant n orbitals. This asymmetry of the n orbitals, if it occurs along the trajectory of addition, is proposed to be generally involved in facial selection in sterically unbiased systems. Experimentally, carbonyl and related olefin compounds, which bear a similar structural motif, exhibit the same facial preference in most cases, particularly in the cases of adamantanes. This feature seems to be compatible with the Cieplak model. However, this is not always the case for other types of molecules, or in reactions such as Diels-Alder cycloaddition. In contrast, unsymmetrization of orbital phase environment, including SOI in Diels-Alder reactions, is a general concept as a contributor to facial selectivity. Other interpretations of facial selectivities have also been reviewed [174-180]. 

It is of interest to investigate the usefulness of this theory to the chemical change involving the interaction between the conjugated systems 56,62,145). Such a-n interactions are frequently stereoselective. The addition to olefinic double bonds and the a, -elimination are liable to take place with the fraMS-mode 146h The Diels-Alder reaction occurs with the cis-fashion with respect to both diene and dienophile. 

The dipole is a triad of atoms which has a n system of four electrons and for which a dipolar resonance form provides an important component of its bonding description. The requirements have also been described as atom A must have a sextet of outer electrons and C has an octet with at least one unshared pair ([119], p. 743). The substrate is an olefin and an alkyne or a carbonyl. The reaction therefore is of n4 + n2 type like the related Diels-Alder reaction and has proved to be very useful synthetically for the construction of 5-membered ring heterocycles [268, 269]. Evidence suggests the reaction is concerted and regioselective. Dipoles fall into two general categories [119] ... 

This obstacle can be overcome by moving electron withdrawing substituents away from the double bond and increasing the reactivity of double bond by positioning it in a strained ring. This is achieved using bicyclic monomers. The monomers are readily obtained from the Diels-Alder reactions of substituted olefins with cyclopentadiene. This route is effective also for fluorinated monomers. These types of monomers undergo a ROMP with a variety of one component and two-component initiator systems. 

There are several cases of polycyclic triazolines, obtained by azide addition to the strained olefinic bond in bi- and tricyclic systems, that are susceptible to retro Diels-Alder reaction to yield 1-substituted triazoles. A well-established example is the monoadduct from norbornadiene and phenyl azide, which decomposes at 90-100°C to give 1-phenyltriazole and a cyclopentadiene (Scheme 138).2s 97—" 1 47 430 Similarly, the cycloadduct from the reaction of 7-oxabenzonorbornadiene and 1-azidoadamantane, when heated at 110°C, affords good yields of l-(l-adamantyl)-l,2,3-triazole in a retro Diels-Alder reaction.155... 

The formation of new bonds in file Diels-Alder reaction requires that file n electrons in file individual diene and olefin n systems become reorganized and shared in file new bonding pattern of the cyclic product. It follows that for this bonding change to occur, file two n systems must overlap so that electrons can move into new orbitals. The most straightforward way file needed orbital overlap can occur is for one n system to function as an electron donor and file other r system to function as an electron acceptor. Therefore file bonding changes in file Diels-Alder reaction result from a donor-acceptor interaction between the diene and olefin jt systems. 

The essential features of the Diels-Alder reaction are a four-electron n system and a two-electron it system which interact by a HOMO-LUMO interaction. The Diels-Alder reaction uses a conjugated diene as the four-electron n system and a it bond between two elements as the two-electron component. However, other four-electron it systems could potentially interact widi olefins in a similar fashion to give cycloaddition products. For example, an allyl anion is a four-electron it system whose orbital diagram is shown below. The symmetry of the allyl anion nonbonding HOMO matches that of the olefin LUMO (as does the olefin HOMO and the allyl anion LUMO) thus effective overlap is possible and cycloaddition is allowed. The HOMO-LUMO energy gap determines the rate of reaction, which happens to be relatively slow in this case. 

Linear tricyclic systems have been obtained from intramolecular photocyclization of l,2-dihydropyridin-2-one to give an olefinic bicyclic product and subsequent Diels-Alder reaction with an acyclic dienophile to give the tricyclic compound. Reactions of this type have been mentioned in Sections 2.04.6.3 and 2.04.7.2. 

Lead tetraalkyl derivatives are used in catalytic systems to polymerise olefines, as catalysts of re-etherification and polycondensation, to speed up the alkylation of lateral chains of alkylbenzenes with ethylene and its derivatives. An addition of lead tetraalkyl derivatives (0.05-2% of alkylben-zene quantity) to catalysts of the liquid-phase oxidation of alkylbenzenes speeds up the oxidation. Tetraethyllead proved to be a good initiator for Diels-Alder reactions to join polymers with alkenylsiloxy chains and can be used as an additive to reduce the attrition and wear of rubbing metal parts. Tetrabutyllead is an active cross-linking agent for polyethylene and modifying agent for plastics. 

Lanthanides in homogeneous systems As organometallics As cerium(IV) salts As coordination complexes As nitrates, chlorides, alkoxides etc. For olefin polymerization For olefin hydrogenation For free radical polymerization For Diels-Alder reactions For olefin polymerization In organic synthesis... 

Since perfluoroalkyl-substituted olefins and alkynes possess low-lying frontier orbitals, [4 + 2] cycloaddition reactions to oxazoles and thiazoles without strongly electron-donating substituents are unfavorable. On the other hand, five-membered heteroaromatic compounds possessing an electron-rich diene substructure, like furans, thiophenes, and pyrroles, should be able to add perfluoroalkyl-substituted olefins as well as alkynes in a normal Diels-Alder process. A reaction sequence consisting of a Diels-Alder reaction with perfluoroalkyl-substituted alkynes as dienophile, and a subsequent retro-Diels-Alder process of the cycloadduct initially formed, represents a preparatively valuable method for regioselective introduction of perfluoroalkyl groups into five-membered heteroaromatic systems. 

The similarity between bicyclobutane and olefins in the type of reactions they undergo is broken by a single marked exception. This is the Diels-Alder reaction which has not been observed in the bicyclobutane system. Although in some cases cycloadducts were obtained, it appears that these reactions occur by a two-step process rather than by a concerted mechanism (see Section V.B). 

Heteroaromatic systems that possess an electron-deficient azadiene are ideally suited for participation in inverse electron-demand Diels-Alder reactions. Additional substitution of the heterocyclic azadiene system with electron-withdrawing groups accents the electron-deficient nature of the heterodiene and permits the use of electron-rich, strained or even simple olefins as dienophiles. 

Although they are often considered as poorer ligands than diphosphines, they lead also to very efficient and attractive enantioselective catalytic systems as exemplified here. As recent examples, diphosphinites 19 and 20 have been involved successfully in hydrogenation of olefins (mostly itaconate derivatives and enamides, up to > 99.9 % ee) ([84-89] and functionalized ketones (21) (up to 86 % ee) [90], hydrocyanation (19) [91], standard Pd-mediated allylic alkylation (20) [92] (up to 86% ee) [93], and Diels-Alder reaction between a,/l-enals and dienes (eq. (4) 99 % ee) [94]. 

Mertes, J., Mattay, J. Thermal reactions of donor-acceptor systems. Part 3. Captodative olefins in normal and inverse Diels-Alder reactions. Helv. Chim. Acta 1988, 71,742-748. 

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