Aggregation of Molecules in Liquid Ethylene Glycol and Its Manifestation in Experimental Raman Spectra and Non-Empirical Calculations

Authors

  • H. Hushvaktov Samarkand State University
  • A. Jumabaev Samarkand State University
  • G. Murodov Samarkand State University
  • A. Absanov Samarkand State University
  • G. Sharifov Samarkand State University

DOI:

https://doi.org/10.15407/ujpe65.4.298

Keywords:

aggregation of molecules, ethylene glycol, spectral manifestation, non-empirical calculations, hydrogen bond, intramolecular interaction, intermolecular interaction, monomer, dimer, aggregate structure

Abstract

Intra- and intermolecular interactions in liquid ethylene glycol have been studied using the Raman spectroscopy method and non-empirical calculations. The results of non-empirical calculations show that an intermolecular hydrogen bond is formed between the hydrogen atom of the OH group in one ethylene glycol molecule and the oxygen atom in the other molecule. The formation of this bond gives rise to a substantial redistribution of charges between those atoms, which, nevertheless, insignificantly changes the bond length. In the corresponding Raman spectra, the presence of hydrogen bonds between the ethylene glycol molecules manifests itself as the band asymmetry and splitting.

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Published

2020-04-17

How to Cite

Hushvaktov, H., Jumabaev, A., Murodov, G., Absanov, A., & Sharifov, G. (2020). Aggregation of Molecules in Liquid Ethylene Glycol and Its Manifestation in Experimental Raman Spectra and Non-Empirical Calculations. Ukrainian Journal of Physics, 65(4), 298. https://doi.org/10.15407/ujpe65.4.298

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Section

Optics, atoms and molecules

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