Spectroscopic and thermodynamic properties of molecular hydrogen dissolved in water at pressures up to 200 MPa

We have measured the Raman Q-branch of hydrogen in a solution with water at a temperature of about 280 K and at pressures from 20 to 200 MPa. From a least-mean-square fitting analysis of the broad Raman Q-branch, we isolated the contributions from the four lowest individual roto-vibrational lines. T...

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Bibliographic Details
Published in:The Journal of chemical physics 2014-04, Vol.140 (16), p.164312-164312
Main Authors: Borysow, Jacek, del Rosso, Leonardo, Celli, Milva, Moraldi, Massimo, Ulivi, Lorenzo
Format: Article
Language:English
Subjects:
AQUEOUS SOLUTIONS
HYDROGEN
Hydrogen storage
INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY
ISOTHERMS
Molar volume
Molecular structure
Physics
SOLUBILITY
SOLUTES
SOLVATION
THERMODYNAMIC MODEL
Thermodynamic models
THERMODYNAMIC PROPERTIES
Vapor phases
Water chemistry
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Summary:We have measured the Raman Q-branch of hydrogen in a solution with water at a temperature of about 280 K and at pressures from 20 to 200 MPa. From a least-mean-square fitting analysis of the broad Raman Q-branch, we isolated the contributions from the four lowest individual roto-vibrational lines. The vibrational lines were narrower than the pure rotational Raman lines of hydrogen dissolved in water measured previously, but significantly larger than in the gas. The separations between these lines were found to be significantly smaller than in gaseous hydrogen and their widths were slightly increasing with pressure. The lines were narrowing with increasing rotational quantum number. The Raman frequencies of all roto-vibrational lines were approaching the values of gas phase hydrogen with increasing pressure. Additionally, from the comparison of the integrated intensity signal of Q-branch of hydrogen to the integrated Raman signal of the water bending mode, we have obtained the concentration of hydrogen in a solution with water along the 280 K isotherm. Hydrogen solubility increases slowly with pressure, and no deviation from a smooth behaviour was observed, even reaching thermodynamic conditions very close to the transition to the stable hydrogen hydrate. The analysis of the relative hydrogen concentration in solution on the basis of a simple thermodynamic model has allowed us to obtain the molar volume for the hydrogen gas/water solution. Interestingly, the volume relative to one hydrogen molecule in solution does not decrease with pressure and, at high pressure, is larger than the volume pertinent to one molecule of water. This is in favour of the theory of hydrophobic solvation, for which a larger and more stable structure of the water molecules is expected around a solute molecule.
ISSN:0021-9606
1089-7690
DOI:10.1063/1.4872039