Sedimentation Equilibrium of Colloidal Suspensions in a Planar Pore Based on Density Functional Theory and the Hard-Core Attractive Yukawa Model

Shiqi Zhou; Hongwei Sun;Shiqi Zhou;Hongwei Sun;

doi:10.1021/jp0462512

Sedimentation Equilibrium of Colloidal Suspensions in a Planar Pore Based on Density Functional Theory and the Hard-Core Attractive Yukawa Model

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ID: 272088

2005

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Abstract

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The sedimentation equilibrium of colloidal suspensions modeled by hard-core attractive Yukawa (HCAY) fluids in a planar pore is studied. The density profile of the HCAY fluid in a gravitational field and its distribution between the pore and uniform phases are investigated by a density functional theory (DFT) approach, which results from employing a recently proposed parameter-free version of the Lagrangian theorem-based density functional approximation (Zhou, S. Phys. Lett. A 2003, 319, 279) for hard-sphere fluids to the hard-core part of the HCAY fluid, and the second-order functional perturbation expansion approximation to the tail part as was done in a recent partitioned density functional approximation (Zhou, S. Phys. Rev. E: Stat. Phys., Plasmas, Fluids, Relat. Interdiscip. Top. 2003, 68, 061201). The resultant DFT approach is, thus, the first adjustable parameter-free DFT for HCAY fluids. The validity of the present DFT for HCAY fluids of reduced range parameter zred = 1.8 under various external potentials is established in the first of the papers cited previously. The present DFT for HCAY fluids can predict the radial distribution function for the bulk HCAY fluid accurately in the colloidal limit (large value of zred), and in the hard-sphere limit, its prediction for the density profile of the hard-sphere fluid in a gravitational field is in very good agreement with the existing simulation data. The dependence of the density profile and distribution coefficient on the magnitude of the interparticle attraction, gravitational field, and degree of confinement is investigated in detail by the present DFT approach. Intuitive and qualitative analyses are also compared with the quantitative DFT calculational results.

Reference Key	sun2005thesedimentation Use this key to autocite in the manuscript while using SciMatic Manuscript Manager or Thesis Manager
Authors	Shiqi Zhou,Hongwei Sun;Shiqi Zhou;Hongwei Sun;
Journal	the journal of physical chemistry b
Year	2005
DOI	10.1021/jp0462512 Searching for DOI...
URL	https://sciprofiles.com/publication/view/1070417d40b63cfb24f3a016193f8973 https://doi.org/10.1021/jp0462512
Keywords	distribution functional fluids pore hard colloidal hcay gravitational field density profile

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