Phenyl nitrene singlet lifetime

Kobayashi et al. [86] studied (4-dimethylamino)phenyl azide by means of laser flash photolysis on a picosecond time scale. They found that the triplet nitrene is formed from an unobserved precursor that has a lifetime of approximately 120ps. By consideration of model compounds, these workers suggested that the precursor is the singlet nitrene, but this conclusion must await confirmation by alternative experiments. However, in this work Kobayashi was able to show that triplet (4-dimethylamino)phenyl nitrene reacts to form the (4-dimethylamino)azobenzene by a kinetically second-order process. 

It is possible to use the effect of temperature on the solution phase product distribution (Table 2) to deduce the lifetime of singlet phenyl nitrene in solution. 

Dilution of toluene with the inert solvent methylene chloride was attempted in an effort to extend the singlet nitrene lifetime and enhance the yield of triplet nitrene [104]. Dilution, however, did not change the ratio of aryl C-H to benzyl C-H insertion products formed, instead the yield of all volatile products decreased at the expense of tar formation. Dilution with CH2C12 did not increase the yield of triplet nitrene derived products such as C6F5NH2 and decafluoroazobenzene, thus the yield of triplet phenyl nitrene is negligible (Table 7) in methylene chloride. The results can be understood with the aid of Scheme 10, which is identical to the mechanistic hypotheses written for parent phenyl azide (Scheme 7). 

Two para-substituents, phenyl and cyano depress and retard the rate of cyclization significantly (Table 11.2)." p-Phenyl and p-cyano are both radical stabilizing substituents. These conjugative substituents reduce the spin density on the carbon ortho to the nitrene nitrogen. The reduced spin density at carbons ortho to the nitrogen lowers the rate at which the 1,3-biradical cychzes. The effect with p-cyano and p-biphenyl singlet phenylnitrene is quite dramatic. The lifetimes of these singlet nitrenes at ambient temperature are 8 and 15 ns, respectively, and the activation barriers to cychzation are 7.2 and 6.8 kcal/mol, respectively. 

The LFP of p-biphenyl azide produces singlet-p-biphenylnitrene. The phenyl group has little influence on the electronic spectra of either singlet or triplet p-biphenylnitrene (Table 11.1), but it extends the singlet nitrene lifetime from 1 to 17 ns at ambient temperature by diluting the spin density ortho to the nitrene nitrogen. 

ESR parameters for triplet carbenes15 and nitrenes16 have been summarized, and it has been shown that phenylnitrene is produced predominantly (87-88%) in the singlet state by direct photolysis of phenyl azide in low-temperature matrices.17 The first spectroscopic observation of a singlet nitrene has been reported nanosecond-laser photolysis of 1-azidopyrene gives the S0 nitrene (Amax 450 nm) which has a lifetime of 22 nsec at room temperature (in benzene) and 34 nsec at 77 K in rigid solution. At room temperature it decays to the triplet ground state (Tj, Amax 415 nm) with a rate constant of about 4.4 x 107 sec. Tt is formed directly by biacetyl sensitized photolysis of the azide. The lifetime of the excited triplet (T2) was about 7 nsec. T dimerizes to azopyrene.18... 

With the assumption that the undetected precursors to triplet 1- and 2-naphthylnitrenes are the azirines seen in the low temperature experiments, we can reach useful conclusions about the photochemistry of polynuclear aromatic azides. First, unlike phenyl azide where the closed-shell singlet intermediate formed in room temperature irradiations is dehydroazepine [46, 49, 69], the intermediates formed from both 1- and 2-naphthyl azide are azirines. The difference in the chemistry of 1- and 2-naphthyl azides is traced to a difference in the lifetime of the respective azirines. The azirine from 2-naphthyl azide survives at least 200 times longer than does the azirine formed from 1-naphthyl azide. The increase in lifetime permits the bimolecular trapping reaction by diethylamine to compete with isomerization to the triplet nitrene in the case of the 2-naphthyl but not the 1-naphthyl azides. 

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