Cycloaddition naphthalenes

Aumann et al. showed that 1,2,4-tridonor-substituted naphthalenes, such as 126, are accessible from 3-donor-substituted propenylidenecarbene complexes 124 containing a (Z)-positioned 3-phenyl substituent and isocyanide (Scheme 26). These transformations constitute formal [5+1] cycloadditions [39, 89, 90]. Since isocyanides are strongly coordinating ligands on chromium, at least... 

Highly functionalized benzenes and naphthalenes have been prepared by cycloaddition of zirconacyclopentadiene 32 and its benzoderivative 33 [38] with... 

Quinone-mono-ketals 46 and 47 are also low reactive dienophiles and are sensitive to Lewis-acid catalysts. The use of high pressure overcomes this limitation [17]. As shown in Equation 5.7, cycloadditions with a variety of substituted 1,3-butadienes 48 occur regioselectively and c This approach provides access to a variety of annulated benzenes and naphthalenes after aromatization of adducts 49. 

Arylethenes are inner-outer-ring dienes in which the vinyl group is linked to an aromatic system. These dienes are poorly or moderately reactive the presence of electron-donating substituents in the diene moiety markedly increases their reactivity. Their cycloadditions are usually accelerated in order to be carried out under mild conditions. 1-Vinylnaphthalene is more reactive than 2-vinyl-naphthalene and styrenes. 

Since dihydroarylethenes are more reactive than the corresponding fully aromatic compounds, their use in the cycloaddition reactions is preferred in order to carry out the reactions under mild conditions with higher yields. Some reactions of 3,4-dihydro-1-vinylnaphthalene (103) [33], 3,4-dihydro-2-vinyl-naphthalene (104) [34], and l,2-dihydro-4-vinylphenanthrene (105) [35] with 4-acetoxy-2-cyclopentenone (98) and 2-inden-l-one (106) are summarized in Schemes 5.11-5.13. 

This silylene formation from 27 under mild conditions permits the synthesis of a variety of interesting carbo- and heterocycles, most of which are new types of compounds. The results are summarized in Schemes 5 and 6. The reactions with benzene and naphthalene represent the first examples of [2+1] cycloadditions of a silylene with aromatic C=C double bonds.59 623 The reactions with carbon disulfide and isocyanide (Scheme 6) are also of great interest because of their unusual reaction patterns.62b... 

A singlet naphthalene or a singlet exciplex is thought to be the reactive species in this reaction since the quantum yield of cycloaddition parallels the quenching of naphthalene fluorescence by acrylonitrile. 

The study of the cycloaddition behavior of l,l-dichloro-2-neopentylsilene, C Si =CHCH2Bu (2) [3], reveals the high polarity of the Si=C bond and a strong electrophilicity. The [4+2] cycloaddition reactions with anthracene (3), cyclopentadiene (4) and fulvenes (5) proceed as expected surprising, however, the Diels-Alder reactions with dienes are of lower activity, like naphthalene (6) and furans (7). 

Although diarylmethylenecyclopropabenzenes react in [4 + 2] cycloadditions at the cyclopropene bridge bond [10a], diarylmethylenecyclopropa[b]-naphthalenes 14 react readily across the exocyclic double bond [10b]. The... 

Diarylmethylenecyclopropa[6]naphthalenes 14, unlike their benzene parent counterparts which give cycloaddition reactions at the cyclopropene bridge bond [10a], react on the exo double bond in Diels-Alder cycloadditions (see Sect. 2.1.1) [10b]. The reactions of 14 with the highly electron-deficient acetylenic(phenyl)iodonium triflate 584 give products 586a and 587, which are believed to derive from unstable primary [2 + 2] cycloadducts 585 (Scheme 82) [10b],... 

The calicene derivative 185 shows ambiguous behavior toward ynamines. Whilst reacting with yndiamine 542 according to the above (2 + 2) mode to give the fulvalene 545300), with ynamine 544 a (4 + 2) cycloaddition mode appears to operate which leads to the naphthalene derivative 545301. This is in accordance with the reactivity of other calicenes toward ADD shown earlier (p. 93). 

Naphthalene and substituted naphthalenes add to olefins 444) (4.39) and to acetylenes445) (4.40) to give 1,2-adducts. In the latter case the primary addition product undergoes a further [2 + 2]intramolecular cycloaddition. 

Scheme 6.53 Products formed by cycloadditions of 3<52-l H-naphthalene (221), liberated from 220 by KOtBu, with furan, 2,5-dimethylfuran and spiro[2.4]hepta-4,6-diene.

Bispropargyl ether 222 isomerized on treatment with tBuOK into the naphthalene 223 via the intramolecular [4+2]-cydoaddition of the phenylallene with the acetylene moiety. Similar reactions of enynyl propargyl ether 224 took place at room temperature to give two isomeric isobenzofurans, 225 and 226. The major product 226 presumably arises from the intramolecular [4 + 2]-cycloaddition of the bisallenyl ether, whereas the minor product 225 is formed by the [4 + 2]-cycloaddition of the monoallenyl ether [180]. 

Use has been made of the C-N cleavage in the conversion of the bicyclic tertiary amines, derived from the 4tc + 2tc cycloaddition of pyrroles and isoindoles with benzynes, into aromatic systems, e.g. naphthalen-l,4-imines and anthracen-9,10-imines yield naphthalenes and anthracenes with the extrusion of the nitrogen bridge [24] in yields which are higher than those obtained by standard oxidation procedures. 

The growth step procedures for the cycloaddition reaction are very simple. Combination of an ethynyl-substituted dendrimer and an excess of the cyclo-pentadienone in a refluxing solvent such as o-xylene, diphenylether, or methyl-naphthalene (with b.p. higher than 130 °C) typically results in quantitative conversion within 24 h. The refluxing of the solvent is necessary to accelerate the elimination of the carbon monoxide in the cycloaddition. The purity of the resulting compounds was checked by MALDI-TOF mass spectrometry which showed quantitative reaction, facilitating work-up. By repeated precipitation in methanol, the pure product can be isolated as white amorphous powders in yields higher than 90%. 

Derivatives of the naphthalen-l,4 -imine ring system (2) have become available only since the discovery of cycloaddition reactions of benzyne, on the one hand, and the recent rapid development of isoindole chemistry on the other. 

In contrast, isomers of 115 have so far not been isolated. An early attempt to generate cyclopropa[a,e]naphthalene (118) failed. More recently, the generation of dicyclopropa[a,c]naphthalene (119) was attempted by reaction of 120 with base. When the aromatization was carried out in the presence of DPIBF (44), stereoi-someric bis-adducts of cyclopropenes were isolated. However, the adducts provide no evidence for the formation of 119 as a reactive intermediate, since they are formed by sequential elimination-cycloaddition via 121. Cyclopropene interception of 121 is faster than further elimination to 119. The failure of the reaction to produce 119 has been attributed to the high strain energy of the product, which is estimated some 2 8 kcal/mol higher than that expected for two isolated cyclopropene units. ... 

H-stacking interactions have also been exploited to orientate olefinic moieties in a geometry suitable for photochemical cycloaddition reactions, and have been invoked by Coates et al. to explain the photodimerization and photopolymerization of mono- and diolefins carrying phenyl and perfiuorophenyl groups [43]. Matsumoto et al. reported the photodimerization of 2-pyridone in co-crystals with naphthalene-substituted monocarboxyhc acids, where the stacking of the naphthalene rings provides carbon-carbon distances appropriate for [4+4] cycloaddition [44]. 

Aryl acetylenes undergo dimerization to give 1-aryl naphthalenes at 180 °C in the presence of ruthenium and rhodium porphyrin complexes. The reaction proceeds via a metal vinylidene intermediate, which undergoes [4 + 2]-cycloaddition vdth the same terminal alkyne or another internal alkyne, and then H migration and aromatization furnish naphthalene products [28] (Scheme 6.29). 

Chiral metal complexes, aUylic alcohol epoxidation catalysis, 394-401 Chiral naphthalene derivatives, singlet oxygen cycloaddition, 271... 

However, when the same reaction was performed in the presence of piperylene, 1,2-cycloaddition was observed to give naphthalene ring fused cyclobutapyrimidines 473 with high regio- and stereoselectivity <2005CPB258>. 

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