Spectroscopic modeling of water molecule

R. I. Danylo; B. A. Okhrimenko

doi:10.1117/12.2042802

7 December 2013 Spectroscopic modeling of water molecule

R. I. Danylo, B. A. Okhrimenko

Proceedings Volume 8923, Micro/Nano Materials, Devices, and Systems; 89235K (2013) https://doi.org/10.1117/12.2042802
Event: SPIE Micro+Nano Materials, Devices, and Applications, 2013, Melbourne, Victoria, Australia

Abstract

This research is devoted to the vibrational spectroscopy inverse problem solution that gives a possibility to design a molecule and make conclusions about its geometry. The valence angle finding based on the usage of inverse spectral vibrational spectroscopy problem is a well-known task. 3N-matrix method was chosen to solve the proposed task. The usage of this method permits to make no assumptions about the molecule force field, besides it can be applied to molecules of matter in liquid state. Anharmonicity constants assessment is an important part of the valence angle finding. The reduction to zero vibrations is necessary because used matrix analytical expression were found in the harmonic approach. In order to find the single-valued inverse spectral problem of vibrational spectroscopy solution a shape parameter characterizing “mixing” of ω₁ and ω₂ vibrations forms must be found. The minimum of such a function Υ called a divergence parameter was found. This function characterizes method’s accuracy. The valence angle assessment was reduced to the divergence parameter minimization. The β value concerning divergence parameter minimum was interpreted as the desired valence angle. The proposed method was applied for water molecule in liquid state: β = (88,8 ±1,7)° . The found angle fits the water molecule nearest surrounding tetrahedral model including hydrogen bond curvature in the first approximation.

Citation Download Citation

R. I. Danylo and B. A. Okhrimenko "Spectroscopic modeling of water molecule", Proc. SPIE 8923, Micro/Nano Materials, Devices, and Systems, 89235K (7 December 2013); https://doi.org/10.1117/12.2042802

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