Electrokinetics: Difference between revisions

Revision as of 09:17, 6 December 2025


⚡️	Electrogravitics	Electrokinetics
🧲	Magnetogravitics	Magnetokinetics

Electrokinetics

Electrokinetics is a branch of physics and chemistry that investigates the electrically induced motion of charged particles, fluids, or interfaces, encompassing a range of interfacial phenomena driven by electric fields or generating them through mechanical means. Key effects include electrophoresis (motion of dispersed particles in a fluid under an electric field), electroosmosis (bulk fluid motion through a porous medium or capillary due to an applied electric field), streaming potential (electric potential generated by fluid flow over a charged surface), and sedimentation potential (electric field from settling charged particles). These phenomena originate from the electrical double layer (EDL) at solid-liquid interfaces, where fixed surface charges are balanced by mobile counterions, leading to tangential forces under external fields. Electrokinetics plays a crucial role in colloid science, with theoretical foundations linking electrostatics, fluid dynamics, and transport processes, and has been quantitatively described since the 19th century. Modern extensions incorporate nonlinear effects, AC fields, and nanoscale considerations for advanced applications.

History

The discovery of electrokinetic phenomena dates back to 1809 when Ferdinand Friedrich Reuss observed electroosmotic flow through porous clay diaphragms under an applied voltage, marking the first documented electrokinetic effect.
- Reuss's experiments demonstrated water movement from anode to cathode, attributing it to electrical forces on charged interfaces.
In 1859, Georg Quincke discovered the streaming potential, establishing the reciprocal nature of electroosmosis and streaming effects.
Theoretical advancements began in 1879 with Hermann von Helmholtz's model of the electrical double layer and the introduction of the zeta potential $\zeta$ $\zeta$ .
- Marian Smoluchowski (1903) derived the Helmholtz–Smoluchowski equation for thin double layers.
- Gouy (1910) and Chapman (1913) developed the diffuse double-layer model, followed by Stern's 1924 combination of fixed and diffuse layers.
The 20th century saw widespread application in colloid chemistry, geophysics, and, from the 1990s onward, microfluidics and nanotechnology.
- Induced-charge electrokinetics (ICEK) was formalized by Bazant et al. in 2004–2010.

Theoretical Basis

Electrokinetics couples the Poisson equation for the electric potential with the Navier–Stokes equations and ion transport (Nernst–Planck).

Poisson equation (electrostatics in the EDL):

\nabla ^{2}\psi =-{\frac {\rho _{e}}{\varepsilon }}

where $\psi$ is the electric potential and $\rho _{e}=F\sum z_{i}c_{i}$ is the charge density.

Helmholtz–Smoluchowski electroosmotic velocity (thin EDL limit, $\kappa a\gg 1$ ):

v_{\mathrm {EO} }=-{\frac {\varepsilon \zeta }{\eta }}\mathbf {E}

Electrophoretic velocity (Hückel–Onsager limit for thick EDL, $\kappa a\ll 1$ ):

v_{\mathrm {EP} }={\frac {2\varepsilon \zeta }{3\eta }}\mathbf {E}

Henry's function $f(\kappa a)$ interpolates between 1 (Hückel) and 1.5 (Smoluchowski).

Streaming potential coefficient:

\left({\frac {\Delta \phi }{\Delta P}}\right)_{I=0}=-{\frac {\varepsilon \zeta }{\eta \sigma }}

Full Poisson–Nernst–Planck–Navier–Stokes (PNP–NS) system for nonlinear and transient electrokinetics:

{\frac {\partial c_{i}}{\partial t}}+\nabla \cdot \left(-D_{i}\nabla c_{i}-{\frac {z_{i}D_{i}F}{RT}}c_{i}\nabla \psi +c_{i}\mathbf {v} \right)=0

\rho \left({\frac {\partial \mathbf {v} }{\partial t}}+\mathbf {v} \cdot \nabla \mathbf {v} \right)=-\nabla p+\eta \nabla ^{2}\mathbf {v} +\rho _{e}\mathbf {E}

Induced-charge electroosmosis (ICEO) slip velocity on polarizable surfaces:

\mathbf {v} _{\mathrm {slip} }=-{\frac {\varepsilon }{\eta }}\langle \mathbf {E} _{t}\rangle \Delta \mathbf {E} _{t}

Dukhin number (surface vs. bulk conduction):

\mathrm {Du} ={\frac {K^{s}}{K^{b}a}}

Applications

Soil and groundwater remediation (electrokinetic remediation) – removal of heavy metals and organic pollutants from low-permeability clays.
Microfluidics – electroosmotic and electrophoretic pumping in lab-on-a-chip devices; capillary electrophoresis for DNA/protein separation.
Biomedical – transdermal drug delivery (iontophoresis), electrophoretic displays (e-ink), cell sorting via dielectrophoresis.
Geophysics – streaming potential surveys for fracture mapping and hydrocarbon exploration.
Energy harvesting – reverse electrodialysis and pressure-driven streaming currents in nanochannels.
Industrial – electrokinetic dewatering of slurries, food processing, and nanoparticle self-assembly.

Discipline	Relevant Mainstream Object/Equation	Role in Electrokinetics
Fluid Dynamics	$\rho \left({\frac {\partial \mathbf {v} }{\partial t}}+\mathbf {v} \cdot \nabla \mathbf {>} \mathbf {v} \right)=-\nabla p+\eta \nabla ^{2}\mathbf {v} +\rho _{e}\mathbf {E}$	Navier–Stokes with body force from electric double layer
Electrochemistry	$\nabla ^{2}\psi =-{\frac {\rho _{e}}{\varepsilon }}$	Poisson equation for potential in the EDL
Colloid Science	$v_{\mathrm {EP} }={\frac {\varepsilon \zeta }{\eta }}\mathbf {E} \cdot f(\kappa a)$	Henry’s equation for particle mobility
Environmental Engineering	$v_{\mathrm {EO} }=-{\frac {\varepsilon \zeta }{\eta }}\mathbf {E}$	Helmholtz–Smoluchowski electroosmotic flow
Microfluidics	$\mu _{\mathrm {ep} }={\frac {\varepsilon \zeta }{\eta }}$	Electrophoretic mobility in capillary electrophoresis
Geophysics	$C_{s}={\frac {\Delta \phi }{\Delta P}}=-{\frac {\varepsilon \zeta }{\eta \sigma }}$	Streaming potential coefficient for subsurface imaging
Biomedical Engineering	$J_{\mathrm {drug} }=-\mu _{\mathrm {EO} }C_{\mathrm {drug} }E$	Iontophoretic flux across skin
Nanotechnology	$\mathbf {F} _{\mathrm {DEP} }=2\pi \varepsilon _{m}r^{3}\mathrm {Re} [K(\omega )]\nabla E^{2}$	Dielectrophoretic force for nanoparticle manipulation
Chemical Engineering	$\mathbf {J} _{i}=-D_{i}\nabla c_{i}-{\frac {z_{i}D_{i}Fc_{i}}{RT}}\nabla \psi +c_{i}\mathbf {v}$	Nernst–Planck flux equation for ion transport
Nonlinear Electrokinetics	$\mathrm {Du} ={\frac {K^{s}}{K^{b}a}},\ \ \mathrm {Wi} ={\frac {\beta Ea}{2D}}$	Dimensionless numbers governing surface-conduction and field-enhanced dissociation effects

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 === History ===
-* The discovery of electrokinetic phenomena dates back to 1809 when Ferdinand Friedrich Reuss observed electroosmotic flow through porous clay diaphragms under an applied voltage, marking the first documented electrokinetic effect and laying the groundwork for understanding fluid motion induced by electricity.
+* The discovery of electrokinetic phenomena dates back to 1809 when Ferdinand Friedrich Reuss observed electroosmotic flow through porous clay diaphragms under an applied voltage, marking the first documented electrokinetic effect.
-** Reuss's experiments demonstrated water movement from anode to cathode, attributing it to electrical forces on charged interfaces, which spurred interest in capillary phenomena.
+** Reuss's experiments demonstrated water movement from anode to cathode, attributing it to electrical forces on charged interfaces.
-*** This work was influenced by earlier electricity studies, including Luigi Galvani's bioelectricity in 1780 and Alessandro Volta's voltaic pile in 1800, providing tools for controlled electric fields.
+* In 1859, Georg Quincke discovered the streaming potential, establishing the reciprocal nature of electroosmosis and streaming effects.
-* In 1859, Georg Quincke discovered the streaming potential, observing electric potentials generated by fluid flow through porous media, establishing the reciprocal nature of electroosmosis and streaming effects.
+* Theoretical advancements began in 1879 with Hermann von Helmholtz's model of the electrical double layer and the introduction of the zeta potential <math>\zeta</math>.
-** Quincke's findings highlighted the Onsager reciprocity in electrokinetics, linking forward and reverse processes thermodynamically.
+** Marian Smoluchowski (1903) derived the Helmholtz–Smoluchowski equation for thin double layers.
-*** Around the same period, in 1873, Wilhelm Hittorf studied ion transport numbers, connecting electrokinetics to electrolysis and ion mobility.
+** Gouy (1910) and Chapman (1913) developed the diffuse double-layer model, followed by Stern's 1924 combination of fixed and diffuse layers.
-* Theoretical advancements began in 1879 with Hermann von Helmholtz's model of the electrical double layer, proposing a capacitor-like structure at interfaces to explain electroosmosis and electrophoresis.
+* The 20th century saw widespread application in colloid chemistry, geophysics, and, from the 1990s onward, microfluidics and nanotechnology.
-** Helmholtz introduced the concept of zeta potential (ζ), the potential at the slipping plane, as a key parameter for electrokinetic forces.
+** Induced-charge electrokinetics (ICEK) was formalized by Bazant et al. in 2004–2010.
-*** Marian Smoluchowski refined this in 1903, developing the Helmholtz-Smoluchowski equation for thin double layers, accounting for viscosity and permittivity in flow velocity calculations.
-* The 20th century saw expansions: In 1923, David L. Chapman and Louis Georges Gouy improved the EDL model with diffuse layer theories, enabling calculations for varying ionic strengths.
-** Otto Stern in 1924 combined Helmholtz's fixed layer with Gouy-Chapman diffuse layer, forming the Stern model still used today.
-*** Post-WWII developments included applications in geophysics (1950s) for soil remediation and in microfluidics (1990s) with lab-on-a-chip devices.
-* Recent history (2000s-2020s) incorporates induced-charge electrokinetics (ICEK), as theorized by Martin Bazant in 2004, addressing nonlinear flows around polarizable surfaces for enhanced mixing and pumping in microdevices.
-** International standards like ISO 13099 (2012) standardized zeta potential measurements, boosting reproducibility in research.
-*** Ongoing work integrates electrokinetics with nanotechnology, such as in nanopore sequencing and energy harvesting from salinity gradients.
 === Theoretical Basis ===
-Electrokinetics is theoretically rooted in the interaction between electric fields and the electrical double layer (EDL) at charged interfaces, where surface charges attract counterions, forming a Stern layer (fixed) and a diffuse layer (mobile). External forces induce slip at the shear plane, characterized by the zeta potential (ζ), leading to relative motion between phases. The core equations derive from coupling Poisson-Boltzmann electrostatics with Navier-Stokes fluid dynamics and Nernst-Planck ion transport.
+Electrokinetics couples the Poisson equation for the electric potential with the Navier–Stokes equations and ion transport (Nernst–Planck).
-* The Helmholtz-Smoluchowski equation for electroosmotic velocity is v_eo = - (ε ζ / η) E, where ε is the dielectric permittivity, η the viscosity, ζ the zeta potential, and E the electric field strength; this assumes thin EDL (κa >> 1, where κ is Debye length inverse and a particle radius).
-** For electrophoresis, the velocity v_ep = (ε ζ / η) E follows similarly, with sign depending on charge; Henry's equation extends this for thick EDL (κa < 1): v_ep = (2 ε ζ / 3 η) E f(κa), where f is a correction factor from 1 to 1.5.
+* Poisson equation (electrostatics in the EDL):
-*** Streaming potential Δφ = (ε ζ / η σ) ΔP, where σ is conductivity and ΔP pressure difference, illustrates reciprocity via Onsager relations.
+:<math>\nabla^2 \psi = -\frac{\rho_e}{\varepsilon}</math>
-* The Poisson-Nernst-Planck (PNP) equations model ion distribution: ∇²ψ = - (ρ_e / ε), with ρ_e from ∑ z_i e n_i, and ∂n_i/∂t = -∇·J_i, J_i = -D_i ∇n_i - (z_i e D_i / kT) n_i ∇ψ + n_i v, incorporating diffusion, migration, and convection.
+where <math>\psi</math> is the electric potential and <math>\rho_e = F \sum z_i c_i</math> is the charge density.
-** In geophysics, the coupled transport equation includes electrokinetic contributions: J = σ ∇ψ + L_ek ∇P, where L_ek is the electrokinetic coefficient, often L_ek = - (ε ζ / η).
-*** For induced-charge electrokinetics, the slip velocity v_s = - (ε / η) (E_t · ∇σ_s) integrates surface conductivity σ_s from induced charges.
+* Helmholtz–Smoluchowski electroosmotic velocity (thin EDL limit, <math>\kappa a \gg 1</math>):
-* Nonlinear effects arise at high fields (Wien effect) or AC excitations, with Dukhin number Du = K_s / (K_b a) quantifying surface vs. bulk conduction, where K_s and K_b are conductivities.
+:<math>v_{\mathrm{EO}} = -\frac{\varepsilon \zeta}{\eta} \mathbf{E}</math>
-** Zeta potential relates to surface chemistry: ζ = (kT / e) arcsinh(σ / (2 ε kT n_0)^{1/2}), from Gouy-Chapman theory for monovalent electrolytes.
-*** In porous media, the effective zeta potential accounts for tortuosity τ: v_eo = - (ε ζ_eff / η τ) E, refining models for soils and rocks.
+* Electrophoretic velocity (Hückel–Onsager limit for thick EDL, <math>\kappa a \ll 1</math>):
+:<math>v_{\mathrm{EP}} = \frac{2\varepsilon \zeta}{3\eta} \mathbf{E}</math>
+Henry's function <math>f(\kappa a)</math> interpolates between 1 (Hückel) and 1.5 (Smoluchowski).
+* Streaming potential coefficient:
+:<math>\left(\frac{\Delta\phi}{\Delta P}\right)_{I=0} = -\frac{\varepsilon \zeta}{\eta \sigma}</math>
+* Full Poisson–Nernst–Planck–Navier–Stokes (PNP–NS) system for nonlinear and transient electrokinetics:
+:<math>\frac{\partial c_i}{\partial t} + \nabla \cdot \left( -D_i \nabla c_i - \frac{z_i D_i F}{RT} c_i \nabla \psi + c_i \mathbf{v} \right) = 0</math>
+:<math>\rho \left( \frac{\partial \mathbf{v}}{\partial t} + \mathbf{v} \cdot \nabla \mathbf{v} \right) = -\nabla p + \eta \nabla^2 \mathbf{v} + \rho_e \mathbf{E}</math>
+* Induced-charge electroosmosis (ICEO) slip velocity on polarizable surfaces:
+:<math>\mathbf{v}_{\mathrm{slip}} = -\frac{\varepsilon}{\eta} \langle \mathbf{E}_t \rangle \Delta \mathbf{E}_t</math>
+* Dukhin number (surface vs. bulk conduction):
+:<math>\mathrm{Du} = \frac{K^s}{K^b a}</math>
 === Applications ===
-* Environmental engineering utilizes electrokinetics for soil and groundwater remediation, where applied DC fields drive contaminants like heavy metals or organics toward electrodes via electroosmosis, electromigration, and electrophoresis, achieving removal efficiencies up to 90% in clay soils.
+* Soil and groundwater remediation (electrokinetic remediation) – removal of heavy metals and organic pollutants from low-permeability clays.
-** Techniques like electrokinetic stabilization enhance soil strength by injecting stabilizers under fields, used in geotechnical projects for foundation improvement.
+* Microfluidics – electroosmotic and electrophoretic pumping in lab-on-a-chip devices; capillary electrophoresis for DNA/protein separation.
-*** In situ applications include permeable reactive barriers coupled with electrokinetics for VOC degradation, with field trials showing reduced remediation times from years to months.
+* Biomedical – transdermal drug delivery (iontophoresis), electrophoretic displays (e-ink), cell sorting via dielectrophoresis.
-* Microfluidics and lab-on-a-chip devices employ electroosmotic pumping for precise fluid control without moving parts, enabling high-throughput analysis in channels <100 μm, with flow rates ~μL/min at 1-10 kV/m.
+* Geophysics – streaming potential surveys for fracture mapping and hydrocarbon exploration.
-** Capillary electrophoresis separates biomolecules like DNA or proteins based on mobility differences, revolutionizing genomics with resolutions down to single-base pairs.
+* Energy harvesting – reverse electrodialysis and pressure-driven streaming currents in nanochannels.
-*** AC electrokinetics facilitates dielectrophoretic trapping and sorting of cells or nanoparticles, applied in diagnostics for cancer cell isolation.
+* Industrial – electrokinetic dewatering of slurries, food processing, and nanoparticle self-assembly.
-* Biomedical applications include drug delivery systems, where electroosmotic flow through skin (iontophoresis) enhances transdermal absorption, used in devices like insulin patches with controlled release rates.
-** Electrophoretic displays (e-ink) rely on particle migration for low-power screens, as in e-readers, with response times ~100 ms.
-*** In tissue engineering, electrokinetic flows manipulate cells in scaffolds, improving nutrient distribution for organoid growth.
-* Geophysics and hydrology use streaming potentials for subsurface characterization, mapping fractures or aquifers by measuring self-potentials from groundwater flow, with sensitivities to permeability variations.
-** Electrokinetic logging in boreholes estimates zeta potentials to infer rock properties like porosity and salinity.
-*** Energy harvesting from salinity gradients via reverse electrodialysis leverages diffusiophoresis, with pilot plants generating mW/cm².
-* Industrial processes apply electrokinetics in dewatering slurries (e.g., mining tailings) via electroosmosis, reducing water content from 50% to 20% efficiently.
-** In food processing, electrophoretic separation purifies proteins or clarifies juices, enhancing yield and quality.
-*** Nanotechnology uses electrokinetics for nanoparticle assembly, forming ordered structures for sensors or catalysts.
 {| class="wikitable"
 ! Discipline !! Relevant Mainstream Object/Equation !! Role in Electrokinetics
 |-
-| Fluid Dynamics || Navier-Stokes with electric terms (ρ (∂v/∂t + v·∇v) = -∇p + η∇²v + ρ_e E) || Describes electrically induced flows and viscous drag in EDL
+| Fluid Dynamics || <math>\rho \left( \frac{\partial \mathbf{v}}{\partial t} + \mathbf{v}\cdot\nabla\mathbf> \mathbf{v} \right) = -\nabla p + \eta \nabla^2 \mathbf{v} + \rho_e \mathbf{E}</math> || Navier–Stokes with body force from electric double layer
 |-
-| Electrochemistry || Zeta potential (ζ = σ / (ε κ)) || Quantifies interface charges for motion prediction and measurement
+| Electrochemistry || <math>\nabla^2 \psi = -\frac{\rho_e}{\varepsilon}</math> || Poisson equation for potential in the EDL
 |-
-| Colloid Science || DLVO theory (V_total = V_A + V_R) with electrostatic repulsion || Explains particle stability, aggregation, and movement in dispersions
+| Colloid Science || <math>v_{\mathrm{EP}} = \frac{\varepsilon \zeta}{\eta} \mathbf{E} \cdot f(\kappa a)</math> || Henry’s equation for particle mobility
 |-
-| Environmental Engineering || Electroosmotic flow rate (Q = - (ε ζ A / η) E) || Applications in remediation processes for contaminant transport
+| Environmental Engineering || <math>v_{\mathrm{EO}} = -\frac{\varepsilon \zeta}{\eta} \mathbf{E}</math> || Helmholtz–Smoluchowski electroosmotic flow
 |-
-| Microfluidics || Capillary electrophoresis mobility (μ_ep = v_ep / E = ε ζ / η) || Precise control and separation of charged species in microchannels
+| Microfluidics || <math>\mu_{\mathrm{ep}} = \frac{\varepsilon \zeta}{\eta}</math> || Electrophoretic mobility in capillary electrophoresis
 |-
-| Materials Science || Dielectric permittivity in fields (D = ε E + P) || Influences electrokinetic efficiency and material selection for devices
+| Geophysics || <math>C_s = \frac{\Delta\phi}{\Delta P} = -\frac{\varepsilon \zeta}{\eta \sigma}</math> || Streaming potential coefficient for subsurface imaging
 |-
-| Geophysics || Streaming potential coefficient (C = Δφ / ΔP = ε ζ / (η σ)) || Mapping subsurface flows and rock properties via self-potentials
+| Biomedical Engineering || <math>J_{\mathrm{drug}} = -\mu_{\mathrm{EO}} C_{\mathrm{drug}} E</math> || Iontophoretic flux across skin
 |-
-| Biomedical Engineering || Iontophoretic flux (J = K E C_d) || Enhances drug delivery through biological membranes
+| Nanotechnology || <math>\mathbf{F}_{\mathrm{DEP}} = 2\pi \varepsilon_m r^3 \mathrm{Re}[K(\omega)] \nabla E^2</math> || Dielectrophoretic force for nanoparticle manipulation
 |-
-| Nanotechnology || Dielectrophoretic force (F_DEP = 2π ε r³ Re[K(ω)] ∇E²) || Manipulation of nanoparticles using non-uniform fields
+| Chemical Engineering || <math>\mathbf{J}_i = -D_i \nabla c_i - \frac{z_i D_i F c_i}{RT} \nabla \psi + c_i \mathbf{v}</math> || Nernst–Planck flux equation for ion transport
 |-
-| Chemical Engineering || Nernst-Planck equation (J_i = -D_i ∇c_i - (z_i F / RT) c_i ∇ψ) || Models ion transport in electrokinetic processes for separations
+| Nonlinear Electrokinetics || <math>\mathrm{Du} = \frac{K^s}{K^b a},\ \ \mathrm{Wi} = \frac{\beta E a}{2D}</math> || Dimensionless numbers governing surface-conduction and field-enhanced dissociation effects
 |}

Electrokinetics: Difference between revisions

Revision as of 09:17, 6 December 2025

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