Photocycloaddition/trapping

Matlin, A. R., Photocycloaddition/Trapping Reactions of Cross conjugated Cyclic Dienones Capture of Oxyallyl Intermediates. In Horspool, W. M., Lenci, F. (eds), CRC Handbook of Organic Photochemistry and Photobiology, 2nd edn, CRC Press LLC, Boca Raton, FL, 2004, Chapter 81, PP- 1 12. 

Photocycloaddition/ Trapping Reactions of Cross-Conjugated Cyclic Dienones Capture of Oxyallyl Intermediates... 

When enamines are employed as sulfene traps, thiete 1,1-dioxides (e.g. 142) can be prepared by subsequent Hofmann elimination of amine. An alternative route to thiete 1,1-dioxides involves trapping sulfenes with ynamines, as illustrated by preparation of (144) (73S534). Certain thietes such as (145) (80LA873, 78TL3617, 78TL4839) are available directly from thioketones by 2 + 2 photocycloaddition with alkynes. 

Further experimental support for the effect of the fragmentation of the 1,4-diradical intermediates on the regioselectivity of the photocycloaddition was recently reported by Weedon and coworkers68 69, who obtained different H,H/H,T ratios between the photocycloproducts [H,H (93) and H,T (94)] and the trapped products 95-98, upon irradiation in the absence of H2Se in the former case and complete trapping of the diradical intermediates in the presence of H2Se in the latter case (Scheme 21). 

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. 

A PET reaction between excess phthalimide (in equilibrium with its conjugate base) and an alkene led to a clean phthalimidation of nonactivated double bonds. Here, the singlet excited state of phthalimide acts as the oxidant and a radical ion pair is formed. The olefin cation radical is trapped by the phthalimide anion, and back electron transfer, followed by protonation, affords the photoaddition products [40], Protected phenethylamines are readily accessible in this way. This reaction has been carried out by using NaOH as the base it has been shown that the amounts (usually equimolar with the alkene) must be carefully chosen in order to avoid the undesired competition with [2 + 2] photocycloaddition. 

The reactions with a,P-unsaturated carbonyl compounds also lead to cyclobutenes (2.102), and there is evidence that, in some cases at least, the mechanism is non-concerted and goes through biradical intermediates that can be trapped by a second molecule of the conjugated alkenc(2.103)- Intramolecular photocycloadditions offer routes to polvcyclic structures, and the cyclobutene unit in the product provides a basis for subsequent chemical transformations such as oxidation (2.104). 

Cyclobutanediones, once exotic compounds represented by a few perhalo derivatives, have become readily available as a result of new synthetic developments in recent years. These include the modified acyloin condensation 52) in which the intermediate enediolate is trapped as bis-trimethylsilyl ether (28) which can be converted to cyclobutanedione by reaction with bromine or hydrolyzed to acyloin and oxidized in a separate step. In addition to this efficient and general method, bi- or polycyclic unsaturated cyclobutanediones (30) have become available from photolysis of bridged cyclohexenediones (29) to be discussed in the following section. Photocycloaddition of dichlorovinylene carbonate (DCVC) to olefins53) promises to provide a third route if the problems associated with hydrolysis of the photoadducts (31) can be overcome. 

TCNE takes place (Scheme 57). Tomioka reported the (3 + 2) photocycloaddition between 1,1,2-triarylcyclopropanes and vinyl ethers in the presence of p-DCB [162]. Mizuno and Otsuji reported the (4 -l- 2) photocycloaddition between 1,2-diarylcyclopropanes and DCA [23]. The 1,4-radical cation produced as an intermediate of the Cope rearrangement of 1,5-dienes via photoinduced electron transfer can be trapped by molecular dioxygen, giving bicyclic dioxanes (Scheme 58) [163]. This photooxygenation takes place in a stereospecific manner. 

Intermolecular de Mayo reactions are efficient for cyclic 1,3-diketones such as dimedone (5,5-dimethyl-l,3-cyclohexanedione)96,103,104 and acyclic systems such as acetylacetone93-95. Unsymmetrical acyclic /l-diketones, such as 1-phenyl-1,3-butanedione98 can enolize in two directions, however, reaction normally occurs preferentially from a single enol form. Examples of alkene photocycloaddition to trapped ends of /(-dicarbonyl compounds (e.g., 2,2-dimethyl-3(2/f)-furanone and 2,2.6-trimethyl-4/f-l,3-dioxin-4-one) are given in Table 1 (entries 26, 27) and Table 2 (entry 35) 10°. If the enol is stabilized by derivatization (e.g., acetylated dimedone 3-acetoxy-5,5-dimethyl-2-cyclohexenone), the primary cyclobutane photoproducts can be isolated96. 

It was shown recently that 1,4-biradicals can be trapped selectively with hydrogen selenide solutions [68]. In all systems examined so far, all possible 1,4-biradicals are produced, as long as their formation was not impeded by steric hindrance. Therefore, the regio- and stereoselectivities of intermolecu-lar 2 -I- 2 photocycloadditions may depend more on the balance between cyclization to cyclobutanes and cleavage of the biradical back to the starting materials than on the first C-C bond formed. An understanding of the steric factors than can control these competitive processes is necessary to predict their stereoselectivity. 

Several reviews have been published within the year which are of general relevance to the photoreactions of aromatic compounds. The subjects of these reviews include photochemistry in ionic liquids and in isotropic and anisotropic media, organic synthesis utilizing photoinduced electron-transfer reactions," heteroatom-directed photoarylation processes, photochromism, and photochemical molecular devices. Reviews more directly pertinent to the sections in the present chapter include those of the photoisomerization of five-membered heteroaromatic azoles, the photocycloaddition of benzene derivatives to alkenes, Diels-Alder additions of anthracenes, advances in the synthesis of polycyclic aromatic compounds, diarylethene-based photochromic switches, the photo-Fries rearrangement, and the application of Diels-Alder trapping of photogenerated o-xylenols to the synthesis of novel compounds. " A number of chapters in the two recently published handbooks of photochemistry and photobiology and in the revised edition of the text on photochromism are also pertinent to the current subject matter. 

Kohmoto, S., Kobayashi, T., Minami, J., Ying, X., Yamaguchi, K., Karatsu, T., Kitamura, A., Kish-ikawa, K., and Yamamoto, M., Trapping of 1,8-biradical intermediates by molecular oxygen in photocycloaddition of naphthyl-N-(naphthylcarbonyl) carboxamides formation of novel 1,8-epid-ioxides and evidence of stepwise aromatic cycloaddition, /. Org. Chem., 66, 66, 2001. 

The photocycloaddition of triplet benzophenone to norbornene was originally reported by Scharf and Korte. The photoproduct 101 that is formed in high exo-selectivity could be thermally cleaved to the 5,e-unsaturated ketone 102, an appHcation of the carbonyl-olefin metathesis (COM) concept. The 1,4-biradical formed in the interaction of norbornene with o-dibenzoyl-benzene was trapped in an intramolecular fashion by the second carbonyl moiety. A highly regioselective reaction of triplet benzophenone was reported with 5-methylenenorborn-2-ene, with preferential attack toward the exo CC double bond. A number of publications have discussed the photocycloaddition reactions of triplet carbonyl compounds to norbornadiene and quadricyclane, as weU as the competition between the Paterno-Biichi reaction and the sensitized norbornadiene/quadricyclane interconversion. Oxetane formation has also been reported for the photoreaction of biacetyl and para-quinones with benzvalene. ... 

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