Cyclic enones, alkenes photocycloaddition

This chapter summarizes and discusses the recent advances in the organic photochemistry of C=C double bonds. Special attention is focused on the photocycloaddition of alkenes to cyclic enones, including the mechanism, regio- and stereoselectivity and synthetic applications of the reaction. 

Prediction of the regioselectivity in the intermolecular photocycloaddition of enones to alkenes following this method provides similar results to those rationalized by the oriented -complex. However, it is in contrast with Weedon s previously discussed trapping results which indicate no selectivity in the first bond formation at the a- or /J-carbon positions in cyclic enones. 

The intermolecular photocycloaddition of alkenes to cyclic enones was found to afford cis- and trans-fused bicyclic systems. This stereoselectivity and the diastereofacial selectivity of chiral alkenes and/or enones is discussed below. 

Demonstration of the unique synthetic utility of the [2 + 2] photocycloaddition reaction of enones to alkenes and the success in controlling the stereoselectivity, to some extent, in the intermolecular additions (discussed above) prompted further studies and development of new synthetic applications in the intramolecular photoadditions during the last decade. In most cases that have been studied, the alkene was tethered to the cyclic enone by three carbon units or two carbons and one heteroatom. 

Schuster, D.I., Kaprinidis, N Wink, D.J., and Dewan, J.C. (1991) Stereochemistry of [2 + 2] photocycloaddition of cyclic enones to alkenes structural and mechanistic considerations in formation of trans-fused cycloadducts. Journal of Organic Chemistry, 56, 561-567. 

The photocycloaddition of (cyclic) a,(B-unsaturated ketones to alkenes affording cyclobutanes as products comprises the four reaction types shown in Sch. 1, i.e., (a) intermolecular enone + alkene cycloaddition (b) cycloisomerization of alkenylsubstituted enones (c) photocyclodimerization of enones, one ground state enone molecule acting as alkene and (d) cycloisomerization of fe-enones. 

In the preparative application of [2 + 2]-photocycloadditions of cyclic enones to (substituted) alkenes, two factors concerning product formation are of decisive relevance, namely the regioselectivity and the (overall) rate of conversion. Regarding the regioselectivity in the addition to mono- and 1,1-disubstituted alkenes, Corey had shown that the preferred addition mode of cyclohex-2-enone to isobutene or 1,1-dimethoxyethylene was the one leading to—both cis- and trans-fused—bicyclo[4.2.0]octan-2-ones with the substituents on C(7) [8]. In contrast, in the reaction with acrylonitrile, the alternate orientation was observed to occur preferentially. Similar results were also reported by Cantrell for the photocycloaddition of 3-methyl-cyclohex-2-enone to differently substituted alkenes [14]. No significant differences in the overall rates of product formation for the different alkenes were observed in these studies. In order to explain these observed... 

The mechanism of the [2 + 2] photocycloaddition of alkenes with cyclenones is a multistep process that involves the addition of alkenes to the 3 7t,tt triplet state of a cyclic enone and the formation of 1,4-biradical intermediates [35]. Except for the reaction of 1-alkenes, up to four new stereogenic centers are formed during the cycloaddition (Scheme 10). 

Introduction of chiral auxiliaries in the starting materials is very attract for applications to organic synthesis. However, to be of synthetic interest, chiral auxiliaries have to be inexpensive, readily introduced on the starting ma rial, inert in the conditions of irradiation, and readily removed from the photo ducts. Even if the first requirements can be easily satisfied with chiral ket esters, and amides, it is often difficult to avoid side reactions involving auxiliary [63]. In order to control all the asymmetric centers created in the in molecular photocycloadditions of cyclic enones with alkenes, esters of c alcohols were first considered. Although menthyl and bomyl derivatives ga only low de, 8-phenylmenthyl esters produced a far better asymmetric inducti [64]. The facial selectivity was found to depend on the syn/anti nature of t cycloadducts and the structure and location of the chiral auxiliary on either tl enone or the alkenyl moiety. More surprisingly the selectivity also depe strongly on the nature of the solvent (Scheme 21). 

Cyclic enones, such as substituted cyclohex-2-enones or cyclohexa-2,5-diones, also undergo sigmatropic photorearrangement to form bicyclo[3.1.0]hexanones (lumiketones) or bicyclo[3.1.0]hex-3-en-2-ones, respectively, for which both concerted and stepwise (biradical) reaction mechanisms have been proposed.640,641,770 For example, a [l,2]-shift concurrently with the ring contraction (termed the type A reaction) is observed upon irradiation of the methylphenyl derivative 159 in polar solvents, whereas phenyl migration (termed the type B reaction) predominates in nonpolar solvents (Scheme 6.70).771,772 The reactions are believed to proceed via both the n,n and n,Tt triplet ketone states. In the presence of alkenes, cyclic enones may readily undergo a competitive photocycloaddition reaction (Section 6.1.5). 

The photocycloaddition reaction of a cyclic enone to a cyclic alkene affords a tricyclic ring system (see II). 

For the photoadducts derived from cyclic enones and alkenes, stereochemistry at the ring junction is influenced by the structure and especially by the ring size of the starting reagents. For steric reasons, only cis-fused cycloadducts can be formed on photocycloaddition of cyclopentenones (n = 0). From cyclohexenone derivatives (n = 1), cis- and transfused adducts can be isolated, even if the cis-fused structure is thermodynamically more stable. This indicates that trans-fused cycloadducts result from a kinetic rather than a thermodynamic control. Fortunately, trans-fused cycloadducts can be epimerized easily to the more stable cis stereoisomers (Scheme 11). 

Stereoselective [2+2] photocycloadditions of alkenes are a powerful tool for the synthesis of cyclobutanes.However, in diastereoselective reactions cyclic enones have been intensively examined with moderate success. By double stereodifferentiation an increase in selectivity was achieved. 

The photochemical reactivity of P-ketoesters is different form that of P-diketones. Irradiation of a P-ketoester in the presence of an alkene produces oxetane via the ketone carbonyl instead of the desired cyclobutane ring system. Therefore, it is necessary to covalently lock the ketoesters as the enol tautomers. To this end, silyl enol ethers, 129 and 132a, and enol acetates, 130 and 132b, were prepared, but these substrates still fail to undergo the desired intramolecular [2 + 2] photocycloaddition with olefins. The only new products observed in these reactions result from the photo-Fries rearrangement of the cyclic enol acetate (130 to 131) and cis-trans isomerization of both acyclic substrates 132a/b. However, tetronates are appropriate substrates for both intermolecular and intramolecular photocycloadditions with olefins. In addition, enol acetates and silyl enol ethers of p-keto esters are known to undergo [2 + 2] photoaddition with cyclic enones (vide infra). 

Mechanistic Issues in [2+21-Photocycloadditions of Cyclic Enones to Alkenes... 

Cyclobutane formation via light-induced [2 + 2] cycloaddition is probably one of the best studied photochemical reactions and has been reviewed thoroughly up to 1972 (Houben-Weyl, Vols. 4/5 a and 4/5 b). The most important types of C —C double-bond chromophores undergoing such reactions arc alkenes, 1,3-dienes, styrenes, stilbenes, arenes, hetarenes, cycloalk-2-enones, cyclohexa-2,4(and 2,5)-dienones, 1,4-benzoquinones, and heteroanalogs of these cyclic unsaturated carbonyl compounds. For p notocyciodimerizations see Houben-Weyl, Vol. 4/5 a, p 278 and for mixed [2 + 2] photocycloadditions of these same chromophores to alkenes see Section 1.3.2.3. 

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