Time-resolved
valence photoelectron spectroscopy is an established
tool for studies of ultrafast molecular dynamics in the gas phase.
Here we demonstrate time-resolved XUV photoelectron spectroscopy from
dilute aqueous solutions of organic molecules, paving the way to application
of this method to photodynamics studies of organic molecules in natural
environments, which so far have only been accessible to all-optical
transient spectroscopies. We record static and time-resolved photoelectron
spectra of a sample molecule, quinoline yellow WS, analyze its electronic
structure, and follow the relaxation dynamics upon excitation with
400 nm pulses. The dynamics exhibit three time scales, of which a
250 ± 70 fs time scale is attributed to solvent rearrangement.
The two longer time scales of 1.3 ± 0.4 and 90 ± 20 ps can
be correlated to the recently proposed ultrafast excited-state intramolecular
proton transfer in a closely related molecule, quinophthalone.
Studies of ultrafast relaxation of molecular chromophores are complicated by the fact that most chromophores of biological and technological importance are rather large molecules and are strongly affected by their...
XUV photoelectron spectroscopy (XPS) is a powerful method for investigating the electronic structures of molecules. However, the correct interpretation of results in the condensed phase requires theoretical models that account for solvation. Here we present experimental aqueous-phase XPS of two organic biomimetic molecular switches, NAIP and p-HDIOP. These switches are structurally similar, but have opposite charges and thus present a stringent benchmark for solvation models which need to reproduce the observed ΔeBE = 1.1 eV difference in electron binding energy compared to the 8 eV difference predicted in the gas phase. We present calculations using implicit and explicit solvent models. The latter employs the average solvent electrostatic configuration and free energy gradient (ASEC-FEG) approach. Both nonequilibrium polarizable continuum models and ASEC-FEG calculations give vertical binding energies in good agreement with the experiment for three different computational protocols. Counterions, explicitly accounted for in ASEC-FEG, contribute to the stabilization of molecular states and reduction of ΔeBE upon solvation.
We use time-resolved photoelectron spectroscopy with wavelength-selected XUV femtosecond pulses to study photoinduced dynamics of organic molecules in solutions at millimolar concentrations. Upon electronic excitation we observe relaxation processes, such as excited state intramolecular proton transfer and trans-cis isomerization.
Time-resolved photoelectron spectropscopy (TRPES) allows tracking ultrafast molecular relaxtion through conical intersections. Here, the implementaion of TRPES for solvated organic molecules is presented and applied to relaxation of aminoazobenzenes as well as several bio-mimetic photoactuators.
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