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Observation of a Zundel-like transition state during proton transfer in aqueous hydroxide solutions
Author(s) -
Sean T. Roberts,
Poul B. Petersen,
Krupa Ramasesha,
Andrei Tokmakoff,
Ivan S. Ufimtsev,
Todd J. Martı́nez
Publication year - 2009
Publication title -
proceedings of the national academy of sciences
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.011
H-Index - 771
eISSN - 1091-6490
pISSN - 0027-8424
DOI - 10.1073/pnas.0901571106
Subject(s) - chemistry , proton , solvation , valence bond theory , hydrogen bond , solvation shell , ion , molecular dynamics , aqueous solution , molecule , chemical physics , infrared spectroscopy , hydroxide , relaxation (psychology) , computational chemistry , inorganic chemistry , organic chemistry , physics , social psychology , molecular orbital , quantum mechanics , psychology
It is generally accepted that the anomalous diffusion of the aqueous hydroxide ion results from its ability to accept a proton from a neighboring water molecule; yet, many questions exist concerning the mechanism for this process. What is the solvation structure of the hydroxide ion? In what way do water hydrogen bond dynamics influence the transfer of a proton to the ion? We present the results of femtosecond pump-probe and 2D infrared experiments that probe the O-H stretching vibration of a solution of dilute HOD dissolved in NaOD/D(2)O. Upon the addition of NaOD, measured pump-probe transients and 2D IR spectra show a new feature that decays with a 110-fs time scale. The calculation of 2D IR spectra from an empirical valence bond molecular dynamics simulation of a single NaOH molecule in a bath of H(2)O indicates that this fast feature is due to an overtone transition of Zundel-like H(3)O(2)(-) states, wherein a proton is significantly shared between a water molecule and the hydroxide ion. Given the frequency of vibration of shared protons, the observations indicate the shared proton state persists for 2-3 vibrational periods before the proton localizes on a hydroxide. Calculations based on the EVB-MD model argue that the collective electric field in the proton transfer direction is the appropriate coordinate to describe the creation and relaxation of these Zundel-like transition states.

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