Water-anion hydrogen bonding dynamics: Ultrafast IR experiments and simulations

Many of water’s remarkable properties arise from its tendency to form an intricate and robust hydrogen bond network. Understanding the dynamics that govern this network is fundamental to elucidating the behavior of pure water and water in biological and physical systems. In ultrafast nonlinear infra...

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Bibliographic Details
Published in:The Journal of chemical physics 2017-06, Vol.146 (23), p.234501-234501
Main Authors: Yamada, Steven A., Thompson, Ward H., Fayer, Michael D.
Format: Article
Language:English
Subjects:
Absorption line
Absorption spectroscopy
Anions
Chemical bonding
Chemical dynamics
Covariance and correlation
Decay rate
Density functional theory
Diffusion rate
Doppler effect
Experiments
Hydrogen bonding
Hydrogen bonds
Infrared spectroscopy
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Interrogation
MATERIALS SCIENCE
Molecular dynamics
Nonlinear systems
Simulation
SOLAR ENERGY
Solvation
Spectrum analysis
Time
Transition moment
Variations
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Summary:Many of water’s remarkable properties arise from its tendency to form an intricate and robust hydrogen bond network. Understanding the dynamics that govern this network is fundamental to elucidating the behavior of pure water and water in biological and physical systems. In ultrafast nonlinear infrared experiments, the accessible time scales are limited by water’s rapid vibrational relaxation (1.8 ps for dilute HOD in H2O), precluding interrogation of slow hydrogen bond evolution in non-bulk systems. Here, hydrogen bonding dynamics in bulk D2O were studied from the perspective of the much longer lived (36.2 ps) CN stretch mode of selenocyanate (SeCN−) using polarization selective pump-probe (PSPP) experiments, two-dimensional infrared (2D IR) vibrational echo spectroscopy, and molecular dynamics simulations. The simulations make use of the empirical frequency mapping approach, applied to SeCN− for the first time. The PSPP experiments and simulations show that the orientational correlation function decays via fast (2.0 ps) restricted angular diffusion (wobbling-in-a-cone) and complete orientational diffusive randomization (4.5 ps). Spectral diffusion, quantified in terms of the frequency-frequency correlation function, occurs on two time scales. The initial 0.6 ps time scale is attributed to small length and angle fluctuations of the hydrogen bonds between water and SeCN−. The second 1.4 ps measured time scale, identical to that for HOD in bulk D2O, reports on the collective reorganization of the water hydrogen bond network around the anion. The experiments and simulations provide details of the anion-water hydrogen bonding and demonstrate that SeCN− is a reliable vibrational probe of the ultrafast spectroscopy of water.
ISSN:0021-9606
1089-7690
DOI:10.1063/1.4984766