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Study of Hydrogen Bonding Patterns of a Pharmaceutically Active Drug Molecule Paraldehyde: a Raman and DFT Study

  • Shweta Singh , Dheeraj K. Singh , Sunil K. Srivastava and Birendra P. Asthana
Published/Copyright: March 16, 2011
Zeitschrift für Physikalische Chemie
From the journal Zeitschrift für Physikalische Chemie Volume 225 Issue 6-7

Abstract

Raman spectra of neat paraldehyde (prldh) and its binary mixtures with methanol (M) with varying mole fractions of prldh from 0.1 to 0.8 were recorded in order to explore the hydrogen bonding patterns of prldh and their influence on spectral features of some selected vibrational bands of prldh in the region 400–1200 cm−1. Only few vibrational bands of paraldehyde show a significant change in their peak position in going from neat prldh to the complexes. One peculiar feature in this study is that the solvent band which occurs at ∼1034 cm−1 shows significant red shift of >4 cm−1 at higher mole fractions of prldh. This red shift is caused due to the hydrogen bonding between the O atom of the prldh ring and H atom of the methanol molecules. The Raman band at ∼1097 cm−1 band shows a blue shift of ∼5 cm−1 upon dilution and its linewidth also shows an increase of ∼5 cm−1 in going from neat prldh to extreme dilution. The line broadening upon dilution clearly indicates that the diffusion mechanism plays a dominant role in the dephasing of this vibrational mode. Density functional theoretic (DFT) calculations were performed employing B3LYP functional and high level basis set, 6-311++G(d,p) to obtain the ground state geometry of neat prldh and its hydrogen bonded complexes with methanol in gas phase. Basis set superimpose error (BSSE) correction was also introduced using the counterpoise method. In order to realize a condition quite close to the experiment, the polarizable continuum model (PCM, specific plus bulk solvation) calculations were also performed. For a detailed vibrational assignment of the normal modes, potential energy distribution (PED) calculation was also performed.

Keywords: Hydrogen Bonding; Binary Mixture [paraldehyde (C6H12O3) + methanol (CH3OH)]; Polarized Raman Study; DFT Calculations; Potential Energy Distribution (PED)
* Correspondence address: Banaras Hindu University, Department of Physics, Varanasi 221005, Indien,
Published Online: 2011-3-16
Published in Print: 2011-7-1

© by Oldenbourg Wissenschaftsverlag, München, Germany

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  3. SERS Study and DFT Simulation of the Interaction of Cytosine with Copper Electrode
  4. Precise Analysis of Small Wavenumber Shift of Pyridine on Dilution with H2O and D2O Using RDS Technique
  5. Deep UV Resonance Raman Spectroscopy with a Tunable 4 kHz Nanosecond Solid-State Laser and a 1 mL Circulating Free-Flow System
  6. Interference Effects in Vibronic 2D-Spectra of Diatomic Molecules
  7. Threshold Photoelectron Spectrum of Isolated NTCDA
  8. Study of Hydrogen Bonding Patterns of a Pharmaceutically Active Drug Molecule Paraldehyde: a Raman and DFT Study
  9. Femtosecond Coherence Spectroscopic Study of the Onset of Chemical Denaturation of Myoglobin upon Addition of Minor Amounts of Urea
  10. Checking and Improving Calibration of Raman Spectra using Chemometric Approaches
  11. The Influence of Short-Day Photoperiods on Bone Composition of Hamsters: a Raman Spectroscopic Investigation
  12. Shell-Isolated Nanoparticle-Enhanced Raman Spectroscopy (SHINERS) Based on Gold-Core Silica-Shell Nanorods
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https://doi.org/10.1524/zpch.2011.0084
Keywords for this article
Hydrogen Bonding; Binary Mixture [paraldehyde (C6H12O3) + methanol (CH3OH)]; Polarized Raman Study; DFT Calculations; Potential Energy Distribution (PED)

Articles in the same Issue

  1. Preface – The Many Facets of Raman Spectroscopy
  2. Vibrational Spectroscopic Studies of Germanium-High Bismuthate Glasses and Vitroceramics
  3. SERS Study and DFT Simulation of the Interaction of Cytosine with Copper Electrode
  4. Precise Analysis of Small Wavenumber Shift of Pyridine on Dilution with H2O and D2O Using RDS Technique
  5. Deep UV Resonance Raman Spectroscopy with a Tunable 4 kHz Nanosecond Solid-State Laser and a 1 mL Circulating Free-Flow System
  6. Interference Effects in Vibronic 2D-Spectra of Diatomic Molecules
  7. Threshold Photoelectron Spectrum of Isolated NTCDA
  8. Study of Hydrogen Bonding Patterns of a Pharmaceutically Active Drug Molecule Paraldehyde: a Raman and DFT Study
  9. Femtosecond Coherence Spectroscopic Study of the Onset of Chemical Denaturation of Myoglobin upon Addition of Minor Amounts of Urea
  10. Checking and Improving Calibration of Raman Spectra using Chemometric Approaches
  11. The Influence of Short-Day Photoperiods on Bone Composition of Hamsters: a Raman Spectroscopic Investigation
  12. Shell-Isolated Nanoparticle-Enhanced Raman Spectroscopy (SHINERS) Based on Gold-Core Silica-Shell Nanorods
  13. Fourier Transform Raman and DFT Study of Blue Shift C–H Stretching Vibration of Diazines on Hydrogen Bond Formation
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