Phenyl azide cycloaddition

Azides can use enamines as dipolarophiles for ],3 cycloadditions to form triazolines. These azides can be formate ester azides (186), phenyl azides (187-195), arylsulfony] azides (191-193,196), or benzoylazides (197,198). For example, the reaction between phenyl azide (138) and the piperidine enamine of propionaldehyde (139) gives 1 -phenyl-4-methy l-5-( 1 -piperidino)-4,5-dihydro-l,2,3-triazole (140), exclusively, in a 53% yield (190). None of the isomeric l-phenyl-5-methyl product was formed. This indicates that the... 

The mechanism of the cycloaddition of phenyl azide to norbornene has been shown to involve a concerted mechanism with a charge imbalance in the transition state (199). In a similar manner the cycloaddition of phenyl azide to enamines apparently proceeds by a concerted mechanism (194, 194a). This is shown by a rather large negative entropy of activation (—36 entropy units for l-(N-morpholino)cyclopentene in benzene solvent at 25°C), indicative of a highly ordered transition state. Varying solvents from those of small dielectric constants to those of large dielectric constants has... 

The kinetics of 1,3-dipolar cycloaddition of phenyl azide to nor-bornene in aqueous solutions was studied (Eq. 12.67).145 As shown in Table 12.1, when the reaction was performed in organic solvents, the reaction showed very small effects of the solvent, while in highly aqueous media, significant accelerations were observed. 

Benzocyclobutene, when generated by oxidation of its iron tricarbonyl complex, can function as the dipolarophile in 1,3-dipolar cycloaddition reactions with arylnitrile oxides (Scheme 113).177 Unfortunately the synthetic versatility of this type of process is limited because of the unreactivity of other 1,3-dipolar species such as phenyl azide, benzonitrile N-phenylimide, and a-(p-tolyl)benzylidenamine N-oxide.177... 

The thermal cycloaddition of azides to acetylenes is the most versatile route to 1,2,3-triazoles, because of the wide range of substituents that can be incorporated into the acetylene and azide components. The accepted mechanism for the reaction is a concerted 1,3-dipolar cycloaddition. The rates of addition of phenyl azide to several acetylenes have been measured the rates of formation of the aromatic triazoles are not appreciably different from the rates of cycloaddition to the corresponding olefins, indicating that the transition-state energy is not lowered significantly by the incipient generation of an aromatic system. 

An example of the reaction of an azide with an allene is known the cycloaddition of phenyl azide to cyanoallene, which gives 4-cyano-5-methyl-l-phenyltriazole. °... 

Alkynes have been well explored as dipolarophiles in the [3 -t- 21-cycloaddition with almost all possible 1,3-dipoles (78), whereas the reaction of iminoboranes as dipolarophiles has focused on covalent azides as 1,3-dipoles. Most well-characterized iminoboranes were reacted with phenyl azide, according to Eq. (52) (11-14,17, 20). 

Cycloaddition of p-methoxyphenyl azide to alkynic dipolarophiles at room temperature gives triazoles (697) and (698) (Equation (54)). A regiospecific addition is only observed in the case of Z = CH(OMe)2 <89H(29)967>. Phenyl azide and substituted benzyl azides undergo 1,3-dipolar cycloadditions with DM AD, phenylacetylene, and ethyl propiolate to afford 1-phenyl- and 1-benzyl-... 

Since the discovery of triazole formation from phenyl azide and dimethyl acetylenedicarboxylate in 1893, synthetic applications of azides as 1,3-dipoles for the construction of heterocychc frameworks and core structures of natural products have progressed steadily. As the 1,3-dipolar cycloaddition of azides was comprehensively reviewed in the 1984 edition of this book (2), in this chapter we recount developments of 1,3-dipolar cycloaddition reactions of azides from 1984 to 2000, with an emphasis on the synthesis of not only heterocycles but also complex natural products, intermediates, and analogues. 

Weinreb and co-workers (16) reported a high-pressure-induced 1,3-dipolar cycloaddition of alkyl and phenyl azides with electron-deficient alkenes at ambient temperature. As a representative example, phenyl azide underwent cycloaddition with methyl crotonate (69) at 12 kbar to give the triazoline 70 (43%) and the p-amino diazoester 71 (53%). The high-pressure conditions resulted in high yield and a shorter reaction time (Scheme 9.16). 

Compound 156 (prepared by reaction of tetrabromocyclopropene and 2,5-dimethylfuran) underwent dipolar cycloaddition with phenyl azide to produce the fused triazole 157. The reaction was carried out in dichloromethane at room temperature over 2 days. This lower reaction temperature allowed for the isolation of the adduct 157, which was established by X-ray crystallographic analysis to be the product of ct>-selective addition. Heating triazole 157 in benzene at reflux for 2 h resulted in ring expansion producing a 1 1 mixture of compounds 158 and 159 (Scheme 16) <2004JOC570>. 

Cycloaddition reactions of C=C double bonds are often facilitated by increased olefinic strain. For example, phenyl azide does not react with unstrained alkenes, but does react readily with the smaller tran -cycloalkenes. Many interesting cycloaUcenes are not sufficiently stable to be isolated, or even observed in solution. However, in many cases they can be trapped by reagents that lead to a 3+2] or [4+2] (Diels-Alder) reaction. 

Photogenerated nitrenes can undergo cycloaddition with alkenes intermolecular reaction leads to aziridine products (5.38), and intramolecular reaction in vinyl azides gives azirines (5.39). The bicyclic azirine from phenyl azide has not been isolated, but it is the intermediate that best accounts for the formation of a substituted azepine when this azide is irradiated in the presence of a secondary amine (5.401. 

The cycloaddition of phenyl azide with 7-f-butoxynorbornadiene proceeds anomalously to produce predominantly the syn- and anfi-endo-triazolines (Scheme 15),99,149 isolated by preparative thin layer chromatography and... 

The strained double bonds in Dewar benzene and thiophene make them good dipolarophiles in 1,3-cycloadditions. The hexamethyl,148 1,3,5-trimethyl, and perfluoro-1,3-dimethyl122 Dewar benzenes all yield a monoadduct by reaction with phenyl azide. The hexafluoro derivative, however, gives, depending on the conditions, either a monoadduct (19) or a mixture of mono-and bisadducts accompanied by an aziridine resulting from thermolysis of the triazoline ring system (Scheme 19).146... 

Schroedel and Schmidpeter reported the preparation of triphenylphosphonio-substituted 1,2,3,4-triazaphospholes 95 by cycloaddition reactions of phosphonium salts 94 (generated in situ from dichlorophosphane 93) with phenyl azide (Scheme 6). A novel phosphoniotriazaphospholide 96 was prepared by the reaction of dichlorophosphane 93 with trimethylsilyl azide and isolated in 28% yield as a relatively stable colorless powder with decomposition point above 105 °C <1997CB89>. 

Phenyl azide is formed from phenyldiazonium chloride and sodium azide by way of two competing reactions (Figure 12.46). The reaction path to the right begins with a 1,3-dipolar cycloaddition. At low temperature, this cycloaddition affords phenylpentazole, which decays above 0°C via a 1,3-dipolar cycloreversion. This cycloreversion produces the 1,3-dipole phenyl azide as the desired product, and molecular nitrogen as a side product. 

The perfluorinated compound (145) was treated with phenyl azide at 70 °C for a total of 27 days to yield 75% of a compound assigned the 3a, 5,6,6a-tetrahydro-37/,47/-pyrrolo[2,3-d]-1,2,3-triazole structure (146), although the regiochemistry of cycloaddition was not determined unambiguously <82JCS(P1)2105>. 

In [3 + 2]-cycloaddition reactions a-ketoenamines serve as synthons, reacting with phenyl azide as the 1,3-dipole component. The resulting tetrahydrophenylcyclopenta-triazol-4-ones are interesting and easily accessible heterocycles329 (equation 247). 

The addition of phenyl azide to / -nitrostyrene gives l,5-diphenyl-4-nitro-1,2,3-triazole (77a) in about 20% yield, identical to the product obtained from bromonitrostyrene, described above.69 Apparently, cycloaddition occurs in both possible orientations the intermediate in one case undergoes dehydrogenation to give 77a (Ar = R = Ph), whereas the other adduct loses nitrous acid to produce 1,4-diphenyl-l,2,3-triazole (78) (Scheme 17). 

FIGURE 18 Top Molecular structure of Rebek s capsule (59) for the acceleration of a 1,3-dipolar cycloaddition between phenylacetylene and phenyl azide. Bottom CAChe-minimized structure of the ternary complex. Symmetrically loaded capsules are also found in solution. (See Color Insert in the back of this book.)... 

Similarly small rate factors were obtained for 1,3-dipolar cycloadditions between diphenyl diazomethane and dimethyl fumarate [131], 2,4,6-trimethylbenzenecarbonitrile oxide and tetracyanoethene or acrylonitrile [811], phenyl azide and enamines [133], diazomethane and aromatic anils [134], azomethine imines and dimethyl acetylenedi-carboxylate [134a], diazo dimethyl malonate and diethylaminopropyne [544] or N-(l-cyclohexenyl)pyrrolidine [545], and A-methyl-C-phenylnitrone and thioketones [812]. Huisgen has written comprehensive reviews on solvent polarity and rates of 1,3-dipolar cycloaddition reactions [541, 542]. The observed small solvent effects can be easily explained by the fact that the concerted, but non-synchronous, bond formation in the activated complex may lead to the destruction or creation of partial charges, connected... 

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