posted on 2018-04-03, 00:00authored byMatthew Ross, Amity Andersen, Zachary W. Fox, Yu Zhang, Kiryong Hong, Jae-Hyuk Lee, Amy Cordones, Anne Marie March, Gilles Doumy, Stephen H. Southworth, Matthew A. Marcus, Robert W. Schoenlein, Shaul Mukamel, Niranjan Govind, Munira Khalil
We present a joint
experimental and computational study of the
hexacyanoferrate aqueous complexes at equilibrium in the 250 meV to
7.15 keV regime. The experiments and the computations include the
vibrational spectroscopy of the cyanide ligands, the valence electronic
absorption spectra, and Fe 1s core hole spectra using element-specific-resonant
X-ray absorption and emission techniques. Density functional theory-based
quantum mechanics/molecular mechanics molecular dynamics simulations
are performed to generate explicit solute–solvent configurations,
which serve as inputs for the spectroscopy calculations of the experiments
spanning the IR to X-ray wavelengths. The spectroscopy simulations
are performed at the same level of theory across this large energy
window, which allows for a systematic comparison of the effects of
explicit solute–solvent interactions in the vibrational, valence
electronic, and core-level spectra of hexacyanoferrate complexes in
water. Although the spectroscopy of hexacyanoferrate complexes in
solution has been the subject of several studies, most of the previous
works have focused on a narrow energy window and have not accounted
for explicit solute–solvent interactions in their spectroscopy
simulations. In this work, we focus our analysis on identifying how
the local solvation environment around the hexacyanoferrate complexes
influences the intensity and line shape of specific spectroscopic
features in the UV/vis, X-ray absorption, and valence-to-core X-ray
emission spectra. The identification of these features and their relationship
to solute–solvent interactions is important because hexacyanoferrate
complexes serve as model systems for understanding the photochemistry
and photophysics of a large class of Fe(II) and Fe(III) complexes
in solution.