Atomic-Scale Observation of Polar Solvation Dynamics Triggered by Photoinduced Charge Transfer in an Organic Chromophore

Solvation plays a key role in photoinduced charge transfer, a fundamental process in many photochemical and biological systems. However, direct experimental observation of the atomic-scale solvent reorganization around an organic molecule following electronic excitation has so far remained elusive. We report time-resolved X-ray scattering measurements of a photoexcited organic hemithioindigo chromophore in the polar solvent acetonitrile, a system containing only light atoms. Exploiting an ~120 fs time resolution and the high X-ray photon flux offered by an X-ray free-electron laser, the experiments capture the ultrafast dipolar rearrangement of the solvent molecules surrounding the solute driven by photoinduced charge transfer. The transient solvation shell structure is found to be formed with a ~0.5 ps time constant and to reequilibrate over ~3 ps as the excited state population returns to the ground state. Transient absorption spectroscopy measurements and molecular dynamics simulations support the interpretation of the structural dynamics. These results demonstrate the viability of using ultrashort X-ray pulses to directly visualize the motion of light atoms in solution, paving the way for atomic-scale understanding and control of photoinduced processes in biological and synthetic photoactive organic molecules.