Depletion and Structural Forces in Confined Polyelectrolyte Solutions

Monte Carlo simulations and density functional calculations have been performed for charged macromolecules confined to planar slits. The force between the confining walls has been evaluated as a function of separation, while keeping the chemical potential of the macromolecules constant. Highly charg...

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Bibliographic Details
Published inLangmuir Vol. 19; no. 23; pp. 9914 - 9922
Main Authors Jönsson, Bo, Broukhno, A, Forsman, J, Åkesson, T
Format Journal Article
LanguageEnglish
Published American Chemical Society 11.11.2003
Subjects
Chemical Sciences
DENSITY-FUNCTIONAL THEORY
FOAM FILMS
Kemi
LIQUID
MEAN-FIELD
MONTE-CARLO SIMULATIONS
Natural Sciences
Naturvetenskap
OSCILLATORY FORCES
POLYMERS
SOLVATION FORCES
SURFACES
SYSTEMS
Teoretisk kemi
Theoretical Chemistry
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Summary:Monte Carlo simulations and density functional calculations have been performed for charged macromolecules confined to planar slits. The force between the confining walls has been evaluated as a function of separation, while keeping the chemical potential of the macromolecules constant. Highly charged spherical particles and flexible polyelectrolyte chains in confinement give rise to depletion and structural oscillatory forces as a function of surface separation. The sign and magnitude of the surface charge of the confining walls have no dramatic effect on the qualitative behavior of the confined liquid. With neutral or oppositely charged surfaces, an accumulation of charged macroions is seen in the slit driven by the repulsive interaction between the macroions, while equally charged surfaces give rise to a pure depletion. The net charge, the range of interaction, and the particle density affect the details of the force curve. For spherical macroions, the period of the oscillations scales approximately as the bulk aggregate concentration, c bulk -1/3. Confined polyelectrolyte chains share some of these properties, but they partly display a different behavior. One clear difference is that the polyelectrolyte net charge, that is, the degree of polymerization, has no effect on the osmotic pressure. This is an indication that polyelectrolyte chains pack not as spheres but rather as cylindrical objects. Another difference is that the effective repulsive interaction between polyelectrolyte chains can be more long ranged and oscillatory forces can appear more readily than for a corresponding solution of equally charged spherical macroions.
Bibliography:istex:5A4E8DBF55FD8C0EF8EAEC06220C3C693EE7CF23
ark:/67375/TPS-2R9267MD-5
ISSN:0743-7463
1520-5827
DOI:10.1021/la034850e