Real-time observation of the photoionization-induced water rearrangement dynamics in the 5-hydroxyindole-water cluster by time-resolved IR spectroscopy

Solvation plays an essential role in controlling the mechanism and dynamics of chemical reactions in solution. The present study reveals that changes in the local solute-solvent interaction have a great impact on the timescale of solvent rearrangement dynamics. Time-resolved IR spectroscopy has been...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2018-01, Vol.20 (5), p.3079-3091
Main Authors: Miyazaki, Mitsuhiko, Naito, Ayumi, Ikeda, Takamasa, Klyne, Johanna, Sakota, Kenji, Sekiya, Hiroshi, Dopfer, Otto, Fujii, Masaaki
Format: Article
Language:English
Subjects:
Chemical reactions
Clusters
Dynamics
Hydration
Infrared spectroscopy
Photoionization
Reaction mechanisms
Solvation
Spectrum analysis
Time constant
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Summary:Solvation plays an essential role in controlling the mechanism and dynamics of chemical reactions in solution. The present study reveals that changes in the local solute-solvent interaction have a great impact on the timescale of solvent rearrangement dynamics. Time-resolved IR spectroscopy has been applied to a hydration rearrangement reaction in the monohydrated 5-hydroxyindole-water cluster induced by photoionization of the solute molecule. The water molecule changes the stable hydration site from the indolic NH site to the substituent OH site, both of which provide a strongly attractive potential for hydration. The rearrangement time constant amounts to 8 ± 2 ns, and is further slowed down by a factor of more than five at lower excess energy. These rearrangement times are slower by about three orders of magnitude than those reported for related systems where the water molecule is repelled from a repulsive part of the interaction potential toward an attractive well. The excess energy dependence of the time constant is well reproduced by RRKM theory. Differences in the reaction mechanism are discussed on the basis of energy relaxation dynamics.
ISSN:1463-9076
1463-9084
DOI:10.1039/c7cp06127g