posted on 2017-06-15, 00:00authored byXin Li, Robert M. Parrish, Fang Liu, Sara I. L. Kokkila Schumacher, Todd J. Martínez
The Frenkel exciton model is a useful
tool for theoretical studies
of multichromophore systems. We recently showed that the exciton model
could be used to coarse-grain electronic structure in multichromophoric
systems, focusing on singly excited exciton states [Acc. Chem. Res. 2014, 47, 2857−2866]. However, our previous implementation excluded charge-transfer
excited states, which can play an important role in light-harvesting
systems and near-infrared optoelectronic materials. Recent studies
have also emphasized the significance of charge-transfer in singlet
fission, which mediates the coupling between the locally excited states
and the multiexcitonic states. In this work, we report on an ab initio
exciton model that incorporates charge-transfer excited states and
demonstrate that the model provides correct charge-transfer excitation
energies and asymptotic behavior. Comparison with TDDFT and EOM-CC2
calculations shows that our exciton model is robust with respect to
system size, screening parameter, and different density functionals.
Inclusion of charge-transfer excited states makes the exciton model
more useful for studies of singly excited states and provides a starting
point for future construction of a model that also includes double-exciton
states.