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Search name	Searched On	Run search
[Keyword: Mg 2 Ni] AND [All Categories: Optics and Laser Physics] (1)	27 Mar 2025	Run
[Keyword: Benzene] AND [All Categories: Computational, Mathematical and Theoretical... (1)	27 Mar 2025	Run
[Keyword: ICP-AES] AND [All Categories: Electrical & Electronic Engineering] (2)	27 Mar 2025	Run
[Keyword: Climate] AND [All Categories: Spectroscopy & Other Analytical Techniq... (1)	27 Mar 2025	Run
[Keyword: Isospin] AND [All Categories: Classical Mechanics, Continuum Physics, Aco... (1)	27 Mar 2025	Run

articleNo Access
LIQUID CRYSTAL MODELING: ELECTROSTATIC AND VAN DER WAALS INTERACTION ENERGIES FOR MOLECULAR BUILDING BLOCKS FROM BENZENE TO CHOLESTEROL
- BELINDA BRAUN,
- MANFRED HOHLA, and
- JUTTA KÖHLER
International Journal of Modern Physics C01 May 1999
Preview Abstract
Intermolecular interaction energies for molecular dimers of benzene, indene, naphthalene, phenanthrene, cholesterol and glycyrrhetinic acid have been calculated according to the CVFF empirical force field of the DISCOVER program. The parallel orientations (side by-side) turned out to be the energetically most favourable ones, in agreement with the parametrization of Gay–Berne potentials. The energies of the T-shape and in-plane (end-to-end) orientations of the entirely asymmetric molecules cholesterol and glycyrrhetinic acid depend strongly on the actual atomic positions. This shows the extent to which the shape and charges of molecules determine all possible orientations and interaction energies in molecular ensembles.

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