Quantum Chemical Approach in the Description of the Amphiphile Clusterization at the Air/Liquid and Liquid/Liquid Interfaces with Phase Nature Accounting. I. Aliphatic Normal Alcohols at the Air/Water Interface

A new model based on the quantum chemical approach is proposed to describe structural and thermodynamic parameters of clusterization for substituted alkanes at the air/liquid and liquid/liquid interfaces. The new model by the authors, unlike the previous one, proposes an explicit account of the liqu...

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Bibliographic Details
Published in:The journal of physical chemistry. B 2015-02, Vol.119 (7), p.3281-3296
Main Authors: Vysotsky, Yuri B, Belyaeva, Elena A, Kartashynska, Elena S, Fainerman, Valentine B, Smirnova, Natalia A
Format: Article
Language:English
Subjects:
Air
Fatty Alcohols - chemistry
Models, Chemical
Quantum Theory
Surface Properties
Thermodynamics
Water - chemistry
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Summary:A new model based on the quantum chemical approach is proposed to describe structural and thermodynamic parameters of clusterization for substituted alkanes at the air/liquid and liquid/liquid interfaces. The new model by the authors, unlike the previous one, proposes an explicit account of the liquid phase (phases) influence on the parameters of monomers, clusters and monolayers of substituted alkanes at the regarded interface. The calculations were carried out in the frameworks of the quantum chemical semiempirical PM3 method (Mopac 2012), using the COSMO procedure. The new model was tested in the calculations of the clusterization parameters of fatty alcohols under the standard conditions at the air/water interface. The enthalpy, Gibbs’ energy and absolute entropy of formation for alcohol monomers alongside with clusterization parameters for the cluster series including the monolayer at air/water interface were calculated. In our calculations the sinkage of monomers, molecules in clusters and monolayers was varied from 1 up to 5 methylene groups. Thermodynamic parameters calculated using the proposed model for the alcohol monolayers are in a good agreement with the corresponding experimental data. However, the proposed model cannot define the most energetically preferable immersion of the monolayer molecules in the water phase.
ISSN:1520-6106
1520-5207
DOI:10.1021/jp512099x