Confirmation of biprotonic phototautomerism in 7-azaindole hydrogen

Montu K. Hazra,, Amit K. Samanta, and, Tapas Chakraborty. Laser Induced Fluorescence Spectroscopy of a Mixed Dimer between 2-Pyridone and 7-Azaindole...
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Confirmation of Biprotonic Phototautomerism in 7-Azaindole Hydrogen-Bonded Dimers' Kenneth C. Ingham, M. Abu-Elgheit, and M. Ashraf El-Bayoumi*

Contribution from the Biophysics Department, Michigan State University, East Lansing, Michigan 48823. Received December 17, 1970 Abstract: The spectral properties of 7-azaindole are compared with those of its N-methyl derivatives. The effect of temperature on the fluorescence of a concentrated solution of 7-azaindole is also investigated. T h e results offer strong- support _ - for the occurrence of an intermolecular double proton-transfer reaction in the lowest excited singlet

electronic state of 7-azaindole hydrogen-bonded dimers. It appears that, at very low temperatures, proton tunneling may be an important mechanism for the reaction.

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iprotonic phototautomerism was first discovered by Taylor, El-Bayoumi, and Kasha2 when they examined the fluorescence spectrum of 7-azaindole in 3-methylpentane as a function of concentration. It was known from earlier work by El-Bayoumi3 that in carbon tetrachloride an appreciable fraction of the 7-azaindole molecules is present in the form of doubly hydrogenbonded self-dimers. By investigating the effect of concentration on the infrared spectrum, an equilibrium constant of 118 l./mol was determined for the dimerization in carbon tetrachloride at room temperature. This value would be expected to be similar in other nonpolar, non-hydrogen-bonding solvents. In Figure 1, the room-temperature fluorescence spectrum of 7-azaindole in 3-methylpentane is seen to consist of two fluorescence bands. The first band, F1, has a maximum at about 325 nm and is attributed to the normal fluorescence of the monomer with possibly a small contribution from the dimer. The second band, F,, has a maximum at about 480 nm and an intensity relative to F1 which depends on concentration, excitation wavelength, and temperature. This second band was attributed2 to fluorescence from a new tautomeric species which forms in the excited state of the dimer by the simultaneous intermolecular transfer of the two indolic protons, as shown in Figure 1. Great care was taken to eliminate alternative explanations of F, such as impurities, excimers, and photodecomposition products. In this paper we wish to present some results which we have obtained in our laboratory as part of a continuing investigation of the 7-azaindole system. In particular, we have synthesized two N-methyl derivatives of 7-azaindole and compared their spectral behavior with that of the parent compound. In addition, we report some initial results from a study on the dependence of the relative intensity of F2/F1on temperature. When taken together, these results confirm the occurrence of biprotonic phototautomerism in 7-azaindole H-bonded dimers. Our experiments also suggest that proton tunneling could be an important mechanism for this process at very low temperatures (