Finite-Thickness and Charge Relaxation in Double-Layer Interactions
Publication date
2006
Authors
Torres, A.
Roij, R. van
Téllez, G.
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DOI
Document Type
Article
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Abstract
We extend the classical Gouy-Chapman model of two planar parallel
interacting double-layers, which is used as a first approximation to
describe the force between colloidal particles, by considering the finitethickness
of the colloids. The formation of two additional double layers
due to this finite thickness, modifies the interaction force compared
to the Gouy-Chapman case, in which the colloids are semi-infinite objects.
In this paper we calculate this interaction force and some other
size-dependent properties using a mean field level of description, based on
the Poisson-Boltzmann (PB) equation. We show that in the case of finitesize
colloids, this equation can be set in a closed form depending on the
geometrical parameters and on their surface charge. The corresponding
linear (Debye-H¨uckel) theory and the well-known results for semi-infinite
colloids are recovered from this formal solution after taking appropriate
limits. We use a density functional corresponding to the PB level of description
to show how in the case when the total colloidal charge is fixed,
it redistribute itself on their surfaces to minimize the energy of the system
depending on the afore mentioned parameters. We study how this charge
relaxation affects the colloidal interactions.