posted on 2017-12-05, 00:00authored byJavier Cerezo, Yanli Liu, Na Lin, Xian Zhao, Roberto Improta, Fabrizio Santoro
We
present a novel mixed quantum classical dynamical method to
include solvent effects on internal conversion (IC) processes. All
the solute degrees of freedom are represented by a wavepacket moving
according to nonadiabatic quantum dynamics, while the motion of an
explicit solvent model is described by an ensemble of classical trajectories.
The mutual coupling of the solute and solvent dynamics is included
within a mean-field framework and the quantum and classical equations
of motions are solved simultaneously. As a test case we apply our
method to the ultrafast ππ* →
nπ* decay of thymine in water. Solvent dynamical response modifies
IC yield already on the 50 fs time scale. This effect is due to water
librational motions that stabilize the most populated state. Pure
static disorder, that is, the existence of different solvent configurations
when photoexcitation takes place, also has a remarkable impact on
the dynamics.