Biswas, Ranjit ; Bagchi, Biman (1996) Self-consistent microscopic treatment of the effects of self-motion of the probe on ionic and dipolar solvation dynamics Journal of Physical Chemistry, 100 (10). pp. 4261-4268. ISSN 0022-3654
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Official URL: http://pubs.acs.org/doi/abs/10.1021/jp952647p
Related URL: http://dx.doi.org/10.1021/jp952647p
Abstract
A simple but self-consistent microscopic theory for the time dependent solvation energy of both ions and dipoles is presented which includes, for the first time, the details of the self-motion of the probe on its own solvation dynamics. The theory leads to several interesting predictions. The most important of them is that, for dipolar solvation, both the rotational and the translational motions of the dipolar solute probe can significantly accelerate the rate of solvation. In addition, the rotational self-motion of the solute can also give rise to an additional mechanism of nonexponentiality in solvation time correlation functions in otherwise slow liquids. A comparison between the present theoretical predictions and the recent experimental studies of Maroncelli et al. on solvation dynamics of aniline in 1-propanol seems to indicate that the said experiments have missed the initial solvent response up to about 45 ps. After mapping the experimental results on the redefined time scale, the theoretical results can explain the experimental results for solvation of aniline in 1-propanol very well. For ionic solvation, the translational motion is significant for light solutes only. For example, for Li+ in water, translational motion speeds up the solvation by about 20%. The present theory demonstrates that in dipolar solvation the partial quenching of the self-motion due to the presence of specific solute-solvent interactions (such as H-bonding) may lead to a much slower solvation than that when the self-motion is present. This point has been discussed. In addition, we present the theoretical results for solvation of aniline in propylene carbonate. Here, the solvation is predicted to be complete within 15-20 ps.
Item Type: | Article |
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Source: | Copyright of this article belongs to American Chemical Society. |
ID Code: | 4333 |
Deposited On: | 18 Oct 2010 08:50 |
Last Modified: | 10 Jan 2011 05:57 |
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