Cycloaddition reactions, alkenes aromatic compounds

A variety of four-membered ring compounds can be obtained with photochemical reactions of aromatic compounds, mainly with the [2 + 2] (ortho) photocycloaddition of alkenes. In the case of aromatic compounds of the benzene type, this reaction is often in competition with the [3 + 2] (meta) cycloaddition, and less frequently with the [4 + 2] (para) cycloaddition (Scheme 5.7) [38-40]. When the aromatic reaction partner is electronically excited, both reactions can occur at the 7t7t singlet state, but only the [2 + 2] addition can also proceed at the %% triplet state. Such competition was also discussed in the context of redox potentials of the reaction partners [17]. Most frequently, it is the electron-active substituents on the aromatic partner and the alkene which direct the reactivity. The [2 + 2] photocycloaddition is strongly favored when electron-withdrawing substituents are present in the substrates. In such a reaction, crotononitrile 34 was added to anisole 33 (Scheme 5.8, reaction 15) [41 ], and only one regioisomer (35) was obtained in good yield. In this transformation, the... 

Three types of cycloaddition products are generally obtained from the photochemical reaction between aromatic compounds and alkenes (Scheme 31). While [2 + 2] (ortho) and [3 + 2] (meta) cycloaddition are frequently described, the [4 + 2] (para or photo-Diels-Alder reaction) pathway is rarely observed [81-83]. Starting from rather simple compounds, polycyclic products of high functionality are obtained in one step. With dissymmetric alkenes, several asymmetric carbons are created during the cycloaddition process. Since many of the resulting products are interesting intermediates for organic syntheses, it is particularly attractive to perform these reactions in a diastereoselective way. 

N-Acyliminium ions are versatile intermediates in organic synthesis they not only react with various nucleophiles such as electron-rich aromatic and heteroaromatic compounds but also undergo cycloaddition reactions with unsaturated compounds.It is especially noteworthy that N-acyliminium ions serve as electron-deficient 4t7 components in [4 + 2] cycloaddition with alkenes and alkynes. " This reaction serves as a useful method for the construction of heterocyclic rings containing a nitrogen atom. Acyclic structures containing amino and hydroxyl groups can also be synthesized from the initially formed cyclic compounds. 

Among the photochemical reactions of aromatic compounds, the photocycloadditions are most frequently applied to the synthesis of complex polycyclic compounds [6, 9]. The [2+3] or meta photocycloaddition of aromatic compounds and alkenes is the most prominent example [10]. This transformation also demonstrates complementarities between photochemical and ground state reactions since such reactions are almost impossible using conventional activation. A [2+2] ot ortho photocycloaddition between carbocyclic aromatic compounds and alkenes is observed as well. It is often competitive with other cycloaddition modes, in particular the [2+3] mode [11]. Many of these reactions are reversible, and photostationary equilibria are involved. This reaction was much less applied to organic synthesis. Recently, it was found that an acidic reaction medium may have an influence on the outeome of the reaction. The intramolecular photocycloaddition of resorcinol derivatives such as 1 is difficult due to its reversibility (Scheme 29.1). However, in an acidic reaction medium, the cycloadducts 2a,b are protonated at the oxygen atom of the tetrahydrofuran moiety... 

Apart from the described radical reaction pathways, there are several important side and consecutive reactions that also proceed in the cracking furnace. The higher the product concentration in the stream (i.e., at high feedstock conversion), the higher is the probability of these side and consecutive reactions. Important side and consecutive reactions include isomerization, cyclization, aromatization, alkylation, and also condensation reactions. The aromatic compounds found in the steam cracker product stream are formed, for example, by cycloaddition reactions of alkenes and dienes followed by dehydrogenation reactions. Moreover, monoaromatic compounds transform into aromatic condensates and polyaromatics (see also Scheme 6.6.2) by the same reactions. Typically, more than 100 different products are found in the product mixture of a commercial steam cracker. 

The photochemical cycloadditions of alkenes and alkynes with aromatic compounds have received by far the most attention. Yields of [2+2] cydoadducts can be good, but reaction times are often long and secondary rearrangement products are common [139, 140, 141,142, 143,144, 145,146] (equations 63-65). The pioneering mechanistic and synthetic work on aromatic photocycloadditions has been reviewed [147],... 

The 3-oxo-2-pyrazolidinium ylides 315, easily available by reaction of the corresponding pyrazolidin-3-one with aromatic aldehydes, function as 1,3-dipoles in cycloaddition reactions with suitable alkenes and alkynes to provide the corresponding products. When unsymmetrical alkynes are used, mixtures of both possible products 316 and 317 are usually obtained (Equation 45). The regioselectivity of cycloadditions of the reaction with methyl propiolate is influenced by the substituents on the aryl residue using several 2,6-di- and 2,4,6-trisubstituted phenyl derivatives only compound 316 is formed <2001HCA146>. Analogous reactions of 3-thioxo-l,2-pyrazolidinium ylides have also been described <1994H(38)2171>. 

There is a striking difference between the photochemical reactivity of oc,(3-unsaturated enones and the corresponding ynones. Whereas many cyclic enones undergo [2+2] cycloaddition to alkenes at the C=C double bond of the enone (probably from the triplet nn state) to yield cyclobutanes, acyclic enones easily deactivate radiationless by rotation about the central C-C single bond. Ynones on the other hand behave much more like alkyl-substituted carbonyl compounds and add to (sterically less encumberd) alkenes to yield oxetanes (Sch. 11) [38,39]. The regioselectivity of the Paterno-Biichi reaction is similar to that of aliphatic or aromatic carbonyl compounds with a preference for primary attack at the less substituted carbon atom (e.g., 41 and 42 from the reaction of but-3-in-2-one 40 with... 

Among these reactions, the photochemical cycloadditions of C=C bom which can create up to four asymmetric carbons during the photochemical sti are particularly interesting, and numerous synthetic applications of this react have been reported. Advances in the understanding of the origin of asymmefa induction, during addition of alkenes with carbonyl derivatives, cyclic enom and aromatic compounds, will be discussed in detail. 

The mechanism of the [3 + 2] cycloaddition is summarized in Scheme The first intermediate results from charge transfer interaction between the eli tronically excited aromatic compound at its singlet state S1 with the alkene w] leads to the formation of the exciplexes K. A more stable intermediate is generated by the formation of two C-C bonds, leading to the intermediates These intermediates have still singlet multiplicity and therefore possess zwii ionic mesomeric structures mainly of type M. In most cases and especially intramolecular reactions, chiral induction occurs during the formation of L. final products are then obtained by cyclopropane formation in the last step. 

Some 3,5-diarylisoxazolidines were prepared hy [3+2]-cycloaddition of C-aryloxaziridines with vinyl aromatic compounds. For example, isoxazolidine 82 was obtained in high yield from oxaziridine 81 and l-methyl-4-vinylbenzene in refluxing toluene. The stereoselectivity of the reaction was greatly affected by the nature of the substituents on the reagents, and in some cases mixtures of cis- and trans-adducts were formed. Experimental data suggested that oxaziridines react directly with alkenes without the intermediate formation of the isomeric nitrones <07T12896>. 

The first carbene compound to be well characterized was prepared in 1966 and was one of many Fischer-Type Carbene Complexes to be reported (see equation 7). Fischer carbenes are characterized by heteroatom substituents at the carbene carbon, stabilization by a low-valent metal center, and a partial positive charge at the carbene carbon. In contrast, Schrock-Type Carbene Complexes, or alkylidenes," that have alkyl substituents, are found on metal centers in higher oxidation states, and are nucleophihc at carbon. Many Fischer carbenes are known for chromium, whereas chromium alkylidenes are much less common. Monohalocarbenes of chromium, for example, (OC)5Cr=C(F)NEt2, have also been extensively investigated." Two carbene reactions of note for their application to organic synthesis are the cycloaddition of alkenes with carbene complexes and the reaction of aromatic carbenes with aUcynes to yield complexed naphthols (the Dotz reaction ). ... 

Whereas Fischer-type chromium carbenes react with alkenes, dienes, and alkynes to afford cyclopropanes, vinylcyclopropanes, and aromatic compounds, the iron Fischer-type carbene (47, e.g. R = Ph) reacts with alkenes and dienes to afford primarily coupled products (58) and (59) (Scheme 21). The mechanism proposed involves a [2 -F 2] cycloaddition of the alkene the carbene to form a metallacyclobutane see Metallacycle) (60). This intermediate undergoes jS-hydride elimination followed by reductive elimination to generate the coupled products. Carbenes (47) also react with alkynes under CO pressure (ca. 3.7 atm) to afford 6-ethoxy-o -pyrone complexes (61). The unstable metallacyclobutene (62) is produced by the reaction of (47) with 2-butyne in the absence of CO. Complex (62) decomposes to the pyrone complex (61). It has been suggested that the intermediate (62) is transformed into the vinylketene complex... 

The areas in which work on alkyne photochemistry has been most prolific are those involving cycloaddition to carbon-carbon double bonds in alkenes, aromatics and related compounds. The simplest type of reaction involves formation of a cyclobutene from an alkene and an alkyne (equation 41) . The cyclobutene product may itself be photolabile, and if radiation is used which is absorbed more strongly by the cyclobutene, the product isolated may be the 1,3-diene derived from it by electrocyclic ring opening (equation 42) . 

Paternd-Biichi reactions [152] this competition has been investigated for electron-rich alkene substrates for several combinations of carbonyl compounds and electron-donors, e.g. a-diketones and ketene acetals [153], aromatic aldehydes and silyl ketene acetals, and enol ethers. In polar solvents, the assumption of a 1,4-zwitterion as decisive intermediate is reasonable. This situation then resembles the sequence observed for ET-induced thermal [2 -I- 2]-cycloaddition reactions [154]. Both regio- and diastereoselectivity are influenced by this mechanistic scenario. The regioselectivity is now a consequence of maximum charge stabilization and no longer a consequence of the primary interaction between excited carbonyl compound and alkene. Whereas 3-alkoxyoxetanes are preferentially formed from triplet excited aldehydes and enolethers, 2-alkoxyoxetanes result from the reaction of triplet excited ketones or aldehydes and highly electron-rich ketene silylacetals (Scheme 40) [155]. 

N-Acyliminium ion pools react with various carbon nucleophiles as summarized in Scheme 5.16. For example, allylsilanes, silyl enol ethers, Grignard reagents, and 1,3-dicarbonyl compounds serve as good nucleophiles. Aromatic and heteroaromatic compounds also react as nucleophiles with N-acyliminium ion pools to give Friedel-Crafts-type alkylation products.N-Acyliminium ions are known to serve as electron-deficient 4n components and undergo [4 -F 2] cycloaddition with alkenes and alkynes. Usually these reactions take place very quickly, and therefore N-acyliminium ion pools serve as effective reagents for flash chemistry. 

The use of 2,4-dinitroi enyl aromatic quaternary salts prepared directly from the parent isoquinoline compound and 2,4-dinitrophenyl bromide or chloride enhances the electron-deficient nature of the iso-quinolinium salts, accelerates the rate of their [4 + 2] cycloaddition reactions with electron-rich alkenes, and has permitted the use of isoquinolinium s ts previously regarded as unmanageable. The application of these observations in the total syntheses of methylamottianamide and 14-epicorynoline is summarized in Scheme 26. ... 

Singlet oxygen ( Ag) generated by triplet sensitization (Section 6.7.1) can readily oxygenate alkenes, dienes and aromatic compounds the reactions are formally interpreted as [2jt + 2jt] ([2 + 2]) or [47t + 27t] ([4 + 2]) cycloaddition reactions, producing 1,2- or 1,4-endoperoxides, respectively. Scheme 6.250 shows examples of the formation of 1,2-dioxetane (513), 3,6-dihydro-l,2-dioxine (514) and 2,3-dioxabicyclo[2.2.2]octa-5,7-diene (515). 

The simultaneous formation of two or more a-bonds has always attracted synthetic chemists since complex molecules can be built up in one single step. Therefore it is not surprising that highly developed syntheses of natural and artificial products often made use of cycloaddition procedures. The meta photocycloaddition of aromatic compounds to alkenes certainly belongs to this category and has reached its summit of application in the admirable work of Wender s group. Hence this chapter describes photocycloadditions of various types covering mainly meta [3+2], ortho [2+2] and para [4+2] ones. Even an unusual example of an [6+6] cycloaddition is presented. The fact that only one substitution reaction is described may indicate that synthetic studies of electron transfer activation only started recently. 

Ketones and aldehydes can undergo photochemical [2-1-2] cycloaddition reactions with alkenes to give oxetanes. This is called the Paterno-Buchi reaction. For alkyl carbonyl compounds both singlet and triplet excited states seem to be involved, but for aromatic compounds the reaction occurs through the triplet state.The regiochemistry can usually be accounted for on the basis of formation of the most stable 2-oxa-1,4-diradical. For example, styrene and benzaldehyde give 2,3- not 2,4-diphenyloxetane. ... 

Sulphonamides have also been prepared from sulphamoyl chlorides by a different procedure. In this method, sulphamoyl chlorides are reacted with a tertiary amine to produce an azasulphene, which is then used in situ for the formation of sulphonamides. A wide structural variety of sulphonamides may be obtained by reaction of azasulphenes with different substrates. Reaction with some substituted alkenes proceeds via either a [2 + 2] cycloaddition reaction as exemplified in equation 102433 or a [2 + 4] cycloaddition reaction as shown in equation 103434,435. Azasulphenes also react with aromatic compounds that are highly activated towards electrophilic substitution as shown in equation 104436. If carboxyethyl azasulphene is used in this reaction, then the unsubstituted aromatic sulphonamide may be obtained in high yield, simply by hydrolysis436 (equation 105). 

Easic Principles Practical Photochemistry General Considerations Carbonyl Compounds a-Cleavage Carbonyl Compounds Hydrogren Abstraction Steroids Carbonyl Compounds Cycloaddition Enone and Dienone Rearrangements Alkenes Isomerisation and Rearrangement Alkenes Cycloaddition Alkenes Photo-Cxidation Terpenoids Aromatic Compounds Isomerisation and Cycloaddition Practical Photochemistry Scale-up Aromatic Compounds Substitution and Cydisation Alkaloids Photoinitiated Free-radical Chain Reactions. 

Other cycloadditions. A [3+2]-cycloaddition involving a benzoquinone and an alkene to give 2,3-dihydrobenzofuran derivatives, and an intramolecular [4+3]-cycloaddition to provide functionalized polycyclic compounds, are further demonstrations of the utility of LiClQj-OEtj. The reaction of aromatic or a,p-unsaturated aldehydes with acid chlorides proceeds via ketenes and then 2-oxetanones. ... 

CAN-mediated nitration provides a convenient route for the introduction of a nitro group into a variety of substrates. Alkenes on treatment with an excess of sodium nitrite and CAN in chloroform under sonication afford nitroalkenes. When acetonitrile is used as the solvent, nitroacetamidation occurs in a Ritter-type fashion. However, the attempted nitroacetamidation of cyclo-pentene-1 -carboxaldehyde under similar conditions resulted in the formation of an unexpected dinitro-oxime compound. A one-pot synthesis of 3-acetyl- or 3-benzoylisoxazole derivatives by reaction of alkenes (or alkynes) with CAN in acetone or acetophenone has been reported. The proposed mechanism involves a-nitration of the solvent acetone, oxidation to generate the nitrile oxide, and subsequent 1,3-dipolar cycloaddition with alkenes or alkynes. The nitration of aromatic compounds such as carbozole, naphthalene, and coumarins by CAN has also been investigated. As an example, coumarin on treatment with 1 equiv of CAN in acetic acid gives 6-nitrocoumarin in 92% yield. ... 

Another aspect of the Diels-Alder reaction that can be rationalized with FMO theory is the regiochemistry observed with unsymmetric dienes or alkenes. Equation 11.45 shows the product distribution from the cycloaddition of 2-phenyl-l,3-butadiene (97) and methyl acrylate (98). The para" product 99 (named by analogy with aromatic compounds) is the major product, but some "meta" product (100) is produced as well. ... 

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