Title of article
Investigation of nanoscale electrohydrodynamic transport phenomena in charged porous materials
Author/Authors
P. Pivonka ، نويسنده , , D. Smith، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2005
Pages
16
From page
1975
To page
1990
Abstract
Depending on the permeability of porous materials, different mass transport mechanisms have to be
distinguished. Whereas mass transport through porous media characterized by low permeabilities is
governed by diffusion, mass transport through highly permeable materials is governed by advection.
Additionally a large number of porous materials are characterized by the presence of surface charge
which affects the permeability of the porous medium. Depending on the ion transport mechanism various
phenomena such as co-ion exclusion, development of diffusion–exclusion potentials, and streaming
potentials may be encountered. Whereas these various phenomena are commonly described by means
of different transport models, a unified description of these phenomena can be made within the
framework of electrohydrodynamics.
In this paper the fundamental equations describing nanoscale multi-ion transport are given. These
equations comprise the generalized Nernst–Planck equation, Gauss’ theorem of electrostatics, and the
Navier–Stokes equation. Various phenomena such as the development of exclusion potentials, diffusion–
exclusion potentials, and streaming potentials are investigated by means of finite element analyses.
Furthermore, the influence of the surface charge on permeability and ion transport are studied in detail
for transient and steady-state problems. The nanoscale findings provide insight into events observed
at larger scales in charged porous materials
Keywords
Nernst–Planck equation , Navier–Stokes equation , Gauss’ theorem , electrohydrodynamic transport , diffuse double-layer
Journal title
International Journal for Numerical Methods in Engineering
Serial Year
2005
Journal title
International Journal for Numerical Methods in Engineering
Record number
425476
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