Your search keyword '"Khrapak, Alexey G."' showing total 2 results

1. Collective modes of two-dimensional classical Coulomb fluids.

Author

Khrapak, Sergey A., Kryuchkov, Nikita P., Mistryukova, Lukia A., Khrapak, Alexey G., and Yurchenko, Stanislav O.

Subjects

CRYSTAL structure, MOLECULAR dynamics, SHEAR waves, APPROXIMATION theory, WAVELENGTHS

Abstract

Molecular dynamics simulations have been performed to investigate in detail collective modes spectra of two-dimensional Coulomb fluids in a wide range of coupling. The obtained dispersion relations are compared with theoretical approaches based on quasi-crystalline approximation, also known as the quasi-localized charge approximation, in the plasma-related context. An overall satisfactory agreement between theory and simulations is documented for the longitudinal mode at moderate coupling and in the long-wavelength domain at strong coupling. For the transverse mode, satisfactory agreement in the long-wavelength domain is only reached at very strong coupling, when the cutoff wave-number below which shear waves cannot propagate becomes small. The dependence of the cutoff wave-number for shear waves on the coupling parameter is obtained. [ABSTRACT FROM AUTHOR]

Published

2018

2. Collective modes in two-dimensional one-component-plasma with logarithmic interaction.

Author

Khrapak, Sergey A., Klumov, Boris A., and Khrapak, Alexey G.

Subjects

DISTRIBUTION (Probability theory), INTERMOLECULAR interactions, MOLECULAR dynamics, MOLECULAR physics, SELF-folding structures & materials

Abstract

The collective modes of a familiar two-dimensional one-component-plasma with the repulsive logarithmic interaction between the particles are analysed using the quasi-crystalline approximation (QCA) combined with the molecular dynamic simulation of the equilibrium structural properties. It is found that the dispersion curves in the strongly coupled regime are virtually independent of the coupling strength. Arguments based on the excluded volume consideration for the radial distribution function allow us to derive very simple expressions for the dispersion relations, which show excellent agreement with the exact QCA dispersion over the entire domain of wavelengths. Comparison with the results of the conventional fluid analysis is performed, and the difference is explained. [ABSTRACT FROM AUTHOR]

Published

2016