Ultrafast Dynamics of Solute Molecules Probed by Resonant Optical Kerr Effect Spectroscopy

Ultrafast molecular dynamics in fluids is of great importance in many biological and chemical systems. Although such dynamics in bulk liquids has been explored by various methods, experimental tools that unveil the dynamics of solvated solutes are limited. In this work, we have developed resonant optical Kerr effect spectroscopy (ROKE), which is an analogue of optical Kerr effect spectroscopy that measures the reorientational relaxation of a dilute solute in solution. By adjusting the pump and probe wavelengths at the resonant absorption band of a solute, the time response of the solute was distinguished easily from the negligible signal of the solvent. The heterodyne detection of ROKE enables the determination of reorientational relaxation time constants with an accuracy of 2.6%. The signal-to-noise ratio was high enough (average similar to 26.7) to obtain an adequate signal from even a 10 mu M solution. Thus, ROKE is a powerful tool to study solute dynamics with high sensitivity in a broad range of applications.

Automated summary

Ultrafast molecular dynamics in fluids is important, but limited experimental tools exist for studying solute dynamics. This study develops resonant optical Kerr effect spectroscopy (ROKE), a powerful and sensitive tool for studying solute dynamics.