posted on 2001-11-09, 00:00authored byFrederick D. Lewis, Xiaobing Zuo, Rajdeep S. Kalgutkar, Jill M. Wagner-Brennan, Miguel A. Miranda, Enrique Font-Sanchis, Julia Perez-Prieto
The temperature-dependent photochemical behavior of 1,3-diphenylpropene and several of its
3-substituted derivatives has been investigated over a wide temperature range. The singlet state is found to
decay via two unactivated processes, fluorescence and intersystem crossing, and two activated processes, trans,cis isomerization and phenyl-vinyl bridging. The latter activated process yields a diradical intermediate which
partitions between ground-state reactant and formation of the di-π-methane rearrangement product. Kinetic
modeling of temperature-dependent singlet decay times and quantum yields of fluorescence, isomerization,
di-π-methane rearrangement, and nonradiative decay provides rate constants and activation parameters for
each of the primary and secondary processes. Substituents at the 3-position are found to have little effect on
the electronic spectra or unactivated fluorescence and intersystem crossing pathways. However, they do effect
the activated primary and secondary processes. Thus, the product ratios are highly temperature dependent.