Your search keyword '"Huet T"' showing total 4 results

1. Unravelling the structural features of monosaccharide glyceraldehyde upon mono-hydration by quantum chemistry and rotational spectroscopy.

Author

Neeman, E. M. and Huet, T. R.

Subjects

*QUANTUM chemistry, *FOURIER transform spectroscopy, *ATOMS in molecules theory, *NATURAL orbitals, *MONOSACCHARIDES, *SINGLE molecules, *MICROWAVE spectroscopy

Abstract

Water is a fundamental molecule for life, and investigating its interaction with monosaccharides is of great interest in order to understand its influence on their conformational behavior. In this study, we report on the conformational landscape of monosaccharide glyceraldehyde, the simplest aldose sugar, in the presence of a single water molecule in the gas phase. This investigation was performed using a combination of Fourier transform microwave spectroscopy and theoretical calculations. Out of the nine calculated conformers, only the lowest energy conformer was experimentally observed and characterized. Interestingly, the presence of water was found to induce structural features in the lowest energy conformer of the glyceraldehyde monomer, with water positioned between the alcohol groups. To analyze this interaction further, non-covalent interaction plots were employed to map the intermolecular interactions in the observed species. Additionally, natural bond orbital analysis was conducted to study the effects of charge transfer in the monohydrate system. Furthermore, topological analysis based on Bader's Atoms in Molecules theory was performed to gain insights into the observed complex. The results of all three analyses consistently showed the formation of relatively strong hydrogen bonds between water and glyceraldehyde, leading to the formation of a seven-member ring network. [ABSTRACT FROM AUTHOR]

Published

2023

2. The conformational landscape of myrtenol: The structure of the hydroxymethyl group and its robustness upon hydration.

Author

Neeman, E. M., Osseiran, N., and Huet, T. R.

Subjects

MICROWAVE spectroscopy, CONFORMATIONAL analysis, FOURIER transform spectroscopy, HYDROXYMETHYL compounds, CONFORMERS (Chemistry), POTENTIAL energy surfaces, NATURAL orbitals, HYDRATION

Abstract

The conformational landscape of myrtenol (2-pinen-10-ol) and its robustness upon hydration were investigated theoretically and experimentally by employing a synergic combination of quantum chemical calculations and Fourier transform microwave spectroscopy coupled to a supersonic jet expansion. Relaxed potential energy surfaces have been carried out, and the lowest energy conformers of the monomer were found to be associated with different geometries of the hydroxymethyl group from those previously reported [Sedo et al., J. Mol. Spectrosc. 356, 32 (2019)]. Geometry optimizations and harmonic vibrational frequency calculations allowed characterization of the equilibrium structure of the possible conformers of myrtenol. Among the nine predicted structures, four have been observed, analyzed, and identified. The controversy on the geometry was solved with the deuteration of the hydroxyl group, which led to the determination of substitution (rs) geometry, in agreement with the present theoretical results. Interestingly, the four observed conformers exhibit the same orientation of OH as in the allyl alcohol molecule. Furthermore, hydrogen bonding linking myrtenol to water was studied. One monohydrate has been observed and identified. Non-covalent interactions and natural bond orbital analysis were performed to depict the interactions responsible for the stabilization of the observed structure. We conclude that the structure of the hydroxymethyl group is robust and does not change upon hydration. [ABSTRACT FROM AUTHOR]

Published

2022

3. Spin-torsion effects in the hyperfine structure of methanol.

Author

Coudert, L. H., Gutlé, C., Huet, T. R., Grabow, J.-U., and Levshakov, S. A.

Subjects

HYPERFINE structure, METHANOL, MOLECULAR beams, MICROWAVE spectroscopy, MOLECULAR rotation, TORSIONAL vibration

Abstract

The magnetic hyperfine structure of the non-rigid methanol molecule is investigated experimentally and theoretically. 12 hyperfine patterns are recorded using molecular beam microwave spectrometers. These patterns, along with previously recorded ones, are analyzed in an attempt to evidence the effects of the magnetic spin-torsion coupling due to the large amplitude internal rotation of the methyl group [J. E. M. Heuvel and A. Dymanus, J. Mol. Spectrosc. 47, 363 (1973)]. The theoretical approach setup to analyze the observed data accounts for this spin-torsion in addition to the familiar magnetic spin-rotation and spin-spin interactions. The theoretical approach relies on symmetry considerations to build a hyperfine coupling Hamiltonian and spin-rotation-torsion wavefunctions compatible with the Pauli exclusion principle. Although all experimental hyperfine patterns are not fully resolved, the line position analysis yields values for several parameters including one describing the spin-torsion coupling. [ABSTRACT FROM AUTHOR]

Published

2015

4. Magnetic hyperfine coupling of a methyl group undergoing internal rotation: A case study of methyl formate.

Author

Tudorie, M., Coudert, L. H., Huet, T. R., Jegouso, D., and Sedes, G.

Subjects

MAGNETIC materials, HYPERFINE interactions, METHYL groups, CASE studies, FORMIC acid, MOLECULAR beams, MICROWAVE spectroscopy, DOPPLER effect

Abstract

The hyperfine structure of methyl formate was recorded in the 2-20 GHz range. A molecular beam coupled to a Fourier transform microwave spectrometer having an instrumental resolution of 0.46 kHz and limited by a Doppler width of a few kHz was used. A-type lines were found split by the magnetic hyperfine coupling while no splittings were observed for E-type lines. Symmetry considerations were used to account for the internal rotation of the methyl top and to derive effective hyperfine coupling Hamiltonians. Neglecting the spin-rotation magnetic coupling, the vanishing splittings of the E-type lines could be understood and analyses of the hyperfine patterns of the A-type lines were performed. The results are consistent with a hyperfine structure dominated by the magnetic spin-spin coupling due to the three hydrogen atoms of the methyl group. [ABSTRACT FROM AUTHOR]

Published

2011