The role of intersystem crossing in the deactivation of the singlet excited aminofluorenones
Literature Information
Publication Date
2001-02-22
DOI
10.1039/B009860O
Impact Factor
3.676
Authors
László Biczók, Tibor Bérces, Tomoyuki Yatsuhashi, Hiroshi Tachibana, Haruo Inoue
View Original
Abstract
Solvent and substituent effects on the competition between internal conversion and triplet formation were studied systematically for aminofluorenones and their N-methylated derivatives. Intersystem crossing (ISC) was found to be the dominant process for the singlet excited 1-amino- and 1-methylaminofluorenone in all solvents. The short fluorescence decay time of these compounds does not originate from intramolecular hydrogen bonding induced internal conversion but it is due to the fast triplet formation. Rather slow (kISC⩽4.8 × 107 s−1) and solvent insensitive intersystem crossing characterizes the photophysical behavior of 2-, 3- and 4-aminofluorenones but their internal conversion rate strongly increases with solvent polarity. The change of the internal conversion rate constants with molecular structure and solvent can be rationalized in terms of the energy gap law.
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Physical Chemistry Chemical Physics
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