posted on 2018-12-05, 00:00authored byGiovanni Bressan, Dale Green, Yohan Chan, Philip C. Bulman Page, Garth A. Jones, Stephen R. Meech, Ismael A. Heisler
The
excited-state energy levels of molecular dimers and aggregates play
a critical role in their photophysical behavior and an understanding
of the photodynamics in such structures is important for developing
applications such as photovoltaics and optoelectronic devices. Here,
exciton transitions in two different covalently bound PBI dimers are
studied by two-dimensional electronic spectroscopy (2DES), a powerful
spectroscopic method, providing the most complete picture of vibronic
transitions in molecular systems. The data are accurately reproduced
using the equation of motion-phase matching approach. The unambiguous
presence of one-exciton to two-exciton transitions are captured in
our results and described in terms of a molecular exciton energy level
scheme based on the Kasha model. Furthermore, the results are supported
by comparative measurements with the PBI monomer and another dimer
in which the interchromophore distance is increased.