posted on 2016-02-19, 04:02authored bySiwar Chibani, Azzam Charaf-Eddin, Boris Le Guennic, Denis Jacquemin
The
simulations of excited-state properties, that is, the 0–0
energies and vibronic shapes, of a large panel of fluorophores presenting
a NBO atomic sequence have been achieved with a Time-Dependent Density
Functional Theory (TD-DFT) approach. We have combined eight hybrid
exchange-correlation functionals (B3LYP, PBE0, M06, BMK, M06-2X, CAM-B3LYP,
ωB97X-D, and ωB97) to the linear-response (LR) and the
state specific (SS) Polarizable Continuum Model (PCM) methods in both
their equilibrium (eq) and nonequilibrium (neq) limits. We show that
the combination of the SS-PCM scheme to a functional incorporating
a low amount of exact exchange can yield unphysical values for molecules
presenting large increase of their dipole moments upon excitation.
We therefore apply a functional possessing a large exact exchange
ratio to simulate the properties of NBO dyes, including large dyads.