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Main Author: Yabunaka, Shunsuke
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.07957
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author Yabunaka, Shunsuke
author_facet Yabunaka, Shunsuke
contents We calculate the drag coefficient of a spherical particle suspended in a near-critical binary fluid mixture. To capture the scaling behavior associated with critical adsorption in the strong adsorption regime, we employ the framework of local renormalized functional theory. Previous theoretical studies encountered numerical difficulties when attempting to solve the coupled hydrodynamic and chemical potential equations, expressed as integral equations, for systems with large bulk correlation lengths. These difficulties limited direct comparison with experimental results. In this study, we overcome those limitations by reformulating the hydrodynamic equations as a set of ordinary differential equations using a compactified radial coordinate. This approach enables more stable numerical computation and facilitates the implementation of appropriate boundary conditions at large distances from the particle. As a result, we successfully compute the drag coefficient over a broader range of bulk correlation lengths than in previous works and compare our theoretical predictions with available experimental data.
format Preprint
id arxiv_https___arxiv_org_abs_2508_07957
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Drag Coefficient in Near-Critical Binary Mixtures: Solving Hydrodynamic Fields with Improved Numerics
Yabunaka, Shunsuke
Soft Condensed Matter
Statistical Mechanics
Chemical Physics
We calculate the drag coefficient of a spherical particle suspended in a near-critical binary fluid mixture. To capture the scaling behavior associated with critical adsorption in the strong adsorption regime, we employ the framework of local renormalized functional theory. Previous theoretical studies encountered numerical difficulties when attempting to solve the coupled hydrodynamic and chemical potential equations, expressed as integral equations, for systems with large bulk correlation lengths. These difficulties limited direct comparison with experimental results. In this study, we overcome those limitations by reformulating the hydrodynamic equations as a set of ordinary differential equations using a compactified radial coordinate. This approach enables more stable numerical computation and facilitates the implementation of appropriate boundary conditions at large distances from the particle. As a result, we successfully compute the drag coefficient over a broader range of bulk correlation lengths than in previous works and compare our theoretical predictions with available experimental data.
title Drag Coefficient in Near-Critical Binary Mixtures: Solving Hydrodynamic Fields with Improved Numerics
topic Soft Condensed Matter
Statistical Mechanics
Chemical Physics
url https://arxiv.org/abs/2508.07957