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Abstract
Path integral molecular simulations are used to explore the nuclear quantum effects (NQEs) on the structure, dihedral landscape and infrared spectrum of ethylene glycol. The simulations are carried out on a new reaction surface Hamiltonian-based model potential energy surface, with especial focus on the role of the OCCO and HOCC dihedrals. By contrast with classical simulations, we analyse how the intramolecular interaction between the OH groups changes due to zero-point effects as well as temperature. These are found to be weak. The NQEs on the free energy profile along the OCCO dihedral are analysed, where notable effects are seen at low temperatures and found to be correlated with the radii of gyration of the atoms. Finally, the power spectrum of the molecule from path integral simulations is compared with the experimental infrared spectrum, yielding good agreement of band positions.
Supplementary materials
Title
Supporting Information for Nuclear Quantum Effects in Gas-Phase Ethylene Glycol
Description
Additional tables and figures, including further ab initio data, plots and tables relating to the model potential, parameters choices for and results from the path integral simulations, are provided. The Fortran 90 code for the PES for EG is available here: https://github.com/arandharamrinal/EG.
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Supplementary weblinks
Title
Potential Energy Surface for Gas-Phase Ethylene Glycol
Description
Fortran codes for the calculations of the potential and forces at an input geometry for ethylene glycol are provided. The full description of the potential model and construction are provided in the main article.
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