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Autores principales: Varma, Vikki Anand, Babu, Sujin B
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2408.17345
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author Varma, Vikki Anand
Babu, Sujin B
author_facet Varma, Vikki Anand
Babu, Sujin B
contents In biological system like cell the macromolecules which are anisotropic particles diffuse in a crowded medium. In the present work we have studied the diffusion of spheroidal particles diffusing between cylindrical obstacles by varying the density of the obstacles as well as the spheroidal particles. Analytical calculation of the free energy showed that the orientational vector of a single oblate particle will be aligned perpendicular and a prolate particle will be aligned parallel to the symmetry axis of the cylindrical obstacles in equilibrium. The nematic transition of the system with and without obstacle remained the same, but in the case of obstacles the nematic vector of the spheroid system always remained parallel to the cylindrical axis. The component of the translational diffusion coefficient of the spheroidal particle perpendicular to the axis of the cylinder is calculated for isotropic system which agrees with analytical calculation. When the cylinders overlap such that the spheroidal particles can only diffuse along the direction parallel to the axis of the cylinder we could observe dimensional confinement. This was observed by the discontinuous fall of the diffusion coefficient, when plotted against the chemical potential both for single particle as well as for finite volume fraction. The rotational diffusion coefficient quickly reached the bulk value as the distance between the obstacle increased in the isotropic phase. In the nematic phase the rotational motion of the spheroid should be arrested. We observed that even though the entire system remained in the nematic phase the oblate particle close to the cylinder underwent flipping motion. The consequence is that when the rotational mean squared displacement was calculated it showed a super-diffusive behavior even though the orientational self correlation function never relaxed to zero.
format Preprint
id arxiv_https___arxiv_org_abs_2408_17345
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Dimensional confinement and superdiffusive rotational motion of uniaxial colloids in the presence of cylindrical obstacles
Varma, Vikki Anand
Babu, Sujin B
Soft Condensed Matter
In biological system like cell the macromolecules which are anisotropic particles diffuse in a crowded medium. In the present work we have studied the diffusion of spheroidal particles diffusing between cylindrical obstacles by varying the density of the obstacles as well as the spheroidal particles. Analytical calculation of the free energy showed that the orientational vector of a single oblate particle will be aligned perpendicular and a prolate particle will be aligned parallel to the symmetry axis of the cylindrical obstacles in equilibrium. The nematic transition of the system with and without obstacle remained the same, but in the case of obstacles the nematic vector of the spheroid system always remained parallel to the cylindrical axis. The component of the translational diffusion coefficient of the spheroidal particle perpendicular to the axis of the cylinder is calculated for isotropic system which agrees with analytical calculation. When the cylinders overlap such that the spheroidal particles can only diffuse along the direction parallel to the axis of the cylinder we could observe dimensional confinement. This was observed by the discontinuous fall of the diffusion coefficient, when plotted against the chemical potential both for single particle as well as for finite volume fraction. The rotational diffusion coefficient quickly reached the bulk value as the distance between the obstacle increased in the isotropic phase. In the nematic phase the rotational motion of the spheroid should be arrested. We observed that even though the entire system remained in the nematic phase the oblate particle close to the cylinder underwent flipping motion. The consequence is that when the rotational mean squared displacement was calculated it showed a super-diffusive behavior even though the orientational self correlation function never relaxed to zero.
title Dimensional confinement and superdiffusive rotational motion of uniaxial colloids in the presence of cylindrical obstacles
topic Soft Condensed Matter
url https://arxiv.org/abs/2408.17345