Water in the Hydration Shell of Halide Ions Has Significantly Reduced Fermi Resonance and Moderately Enhanced Raman Cross Section in the OH Stretch Regions

Water in the presence of electrolytes plays an important role in biological and industrial processes. The properties of water, such as the intermolecular coupling, Fermi resonance (FR), hydrogen-bonding, and Raman cross section were investigated by measuring the Raman spectra in the OD and OH stretc...

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Bibliographic Details
Published in:The journal of physical chemistry. B 2013-08, Vol.117 (33), p.9728-9733
Main Authors: Ahmed, Mohammed, Singh, Ajay K, Mondal, Jahur A, Sarkar, Sisir K
Format: Article
Language:English
Subjects:
Alkali halides
Bromides - chemistry
Charge transfer
Condensed matter: structure, mechanical and thermal properties
Cross sections
Deuterium Oxide - chemistry
Dilution
Exact sciences and technology
Halides
Halogens - chemistry
Hydration
Hydrogen Bonding
Hydroxides - chemistry
Ions - chemistry
Joining
Lattice dynamics
Physics
Sodium Compounds - chemistry
Spectra
Spectrum Analysis, Raman
Vibrational states in disordered systems
Water - chemistry
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Summary:Water in the presence of electrolytes plays an important role in biological and industrial processes. The properties of water, such as the intermolecular coupling, Fermi resonance (FR), hydrogen-bonding, and Raman cross section were investigated by measuring the Raman spectra in the OD and OH stretch regions in presence of alkali halides (NaX; X = F, Cl, Br, I). It is observed that the changes in spectral characteristics by the addition of NaX in D2O are similar to those obtained by the addition of H2O in D2O. The spectral width decreases significantly by the addition of NaX in D2O (H2O) than that in the isotopically diluted water. Quantitative estimation, on the basis of integrated Raman intensity, revealed that the relative Raman cross section, σH/σb (σH and σb are the average Raman cross section of water in the first hydration shell of X– and in bulk, respectively), in D2O and H2O is higher than those in the respective isotopically diluted water. These results suggest that water in the hydration shell has reduced FR and intermolecular coupling compared to those in bulk. In the isotopically diluted water, the relative Raman cross section increases with increase in size of the halide ions (σH/σb = 0.6, 1.1, 1.5, and 1.9 for F–, Cl–, Br–, and I–, respectively), which is assignable to the enhancement of Raman cross section by charge transfer from halide ions to the hydrating water. Nevertheless, the experimentally determined σH/σb is lower than the calculated values obtained on the basis of the energy of the charge transfer state of water. The weak enhancement of σH/σb signifies that the charge transfer transition in the hydration shell of halide ions causes little change in the OD (OH) bond lengths of hydrating water.
ISSN:1520-6106
1520-5207
DOI:10.1021/jp403618x