Self-Consistent Approach to Global Charge Neutrality in Electrokinetics: A Surface Potential Trap Model

Wan, Li; Xu, Shixin; Liao, Maijia; Li, Chun; Sheng, Ping

doi:10.1103/physrevx.4.011042

Cited by 38 publications

(61 citation statements)

References 117 publications

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“…To describe clearly the curvature effects on the thin EDL, it suffices to establish pointwise descriptions for boundary layer solutions near the boundary. Based upon [28,29,38,48,52] for boundary layer solutions of the CCPB equations, in this work we focus mainly on an electrolyte environment involving the mixture of one anion species with the charge valence −pe 0 and one cation species with the charge valence +qe 0 (p, q > 0 and e 0 is the elementary charge). Let Ω be a bounded domain in R N (N ≥ 2), where the boundary ∂Ω associated with the charged surface is smooth.…”

Section: Background and Problem Formulationmentioning

confidence: 99%

“…The Neumann boundary condition (1.2) is considered for a given surface charge distribution C bd at the charged surface; the Robin boundary condition (1.5) is related to the capacitance effect of the EDL, where η is related to the thickness of the Stern layer [2]. We refer the reader to [25,37,40,48,52] for the more details of the physical background information of the model (1.7)-(1.8) and boundary conditions (1.2) and (1.5).…”

Section: Some Physical Quantitiesmentioning

confidence: 99%

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Thin layer analysis of a non-local model for the double layer structure

Lee

2019

Journal of Differential Equations

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For the structure of the thin electrical double layer (EDL) and the property related to the EDL capacitance, we analyze boundary layer solutions (corresponding to the electrostatic potential) of a non-local elliptic equation which is a steady-state Poisson-Nernst-Planck equation with a singular perturbation parameter related to the small Debye screening length. Theoretically, the boundary layer solutions describe that those ions exactly approach neutrality in the bulk, and the extra charges are accumulated near the charged surface. Hence, the non-neutral phenomenon merely occurs near the charged surface. To investigate such phenomena, we develop new analysis techniques to investigate thin boundary layer structures. A series of fine estimates combining the Pohožaev's identity, the inverse Hölder type estimates and some technical comparison arguments are developed in arbitrary bounded domains. Moreover, we focus on the physical domain being a ball with the simplest geometry and gain a clear picture on the effect of the curvature on the boundary layer solutions. The content involves three contributions. The first one focuses mainly on the boundary concentration phenomena. We show that the net charge density behaves exactly as Dirac delta measures concentrated at boundary points. The second one is devoted to pointwise descriptions with curvature effects for the thin boundary layer. An interesting outcome shows that the significant curvature effect merely occurs in the part of the boundary layer close to the boundary, and this part is extremely thinner than the whole boundary layer. The third contribution gives a connection to the EDL capacitance. We provide a theoretical way to support that the EDL has higher capacitance in a quite thin region near the charged surface, not in the whole EDL. In particular, for the cylindrical electrode, our result has a same analogous measurement as the specific capacitance of the well-known Helmholtz double layer.Mathematics Subject Classification. 34E05 · 35J67 · 35Q92 · 35R09.

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Section: Background and Problem Formulationmentioning

confidence: 99%

Section: Some Physical Quantitiesmentioning

confidence: 99%

Thin layer analysis of a non-local model for the double layer structure

Lee

2019

Journal of Differential Equations

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“…Dielectrophoresis (DEP) is defined as the motion imparted on polarized particles in suspension by exposure to a gradient AC electric field; along with other electro‐mechanical effects , DEP is a longstanding issue both in pure physics and a variety of scientific and technological fields. The past few decades have seen rapid growth in the use of DEP for collecting, manipulating, and discriminating particles or biological cells suspended in liquids, due to improvements in micro‐fabrication techniques .…”

Section: Introductionmentioning

confidence: 99%

Modeling and simulation of dielectrophoretic collective dynamics in a suspension of polarizable particles under the action of a gradient AC electric field

2017

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When a suspension of polarizable particles is subjected to a gradient AC electric field, the particles exhibit collective motion due to an interaction between the dipole induced in the particles and the spatial gradient of the electric field; this is known as dielectrophoresis. In the present study, the collective dynamics of suspended particles in a parallel-plate electric chamber was investigated by simulating numerically the trajectories of individual particles under the action of combined dielectrophoretic and dipole-dipole interparticle forces. The particles were transported by the dielectrophoretic forces toward the grounded electrodes. Before long, when the particles approached the site of the minimum field strength, attractive/repulsive interparticle forces became dominant and acted among the particles attempting to form a column-like cluster, having the particles distribution in concentric circles in its cross-section, in line with the centerline of the grounded electrodes. Our results also well reproduced the transient particle aggregation that was observed experimentally.

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“…To increase the efficiency of numerical simulations, one may use the (multi-species) Poisson-Nernst-Planck (PNP) system [19,27,28,54,62], which is a macroscopic model to describe multispecies ion transport. Conventionally, the PNP system consists of coupled diffusion-convection equations and the Poisson equation being represented as follows:…”

Section: Introductionmentioning

confidence: 99%

Diffusion Limit of Kinetic Equations for Multiple Species Charged Particles

Lin

Chun

2014

Arch Rational Mech Anal

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In ionic solutions, there are multi-species charged particles (ions) with different properties like mass, charge etc. Macroscopic continuum models like the Poisson-Nernst-Planck (PNP) systems have been extensively used to describe the transport and distribution of ionic species in the solvent. Starting from the kinetic theory for the ion transport, we study a Vlasov-Poisson-Fokker-Planck (VPFP) system in a bounded domain with reflection boundary conditions for charge distributions and prove that the global renormalized solutions of the VPFP system converge to the global weak solutions of the PNP system, as the small parameter related to the scaled thermal velocity and mean free path tends to zero. Our results may justify the PNP system as a macroscopic model for the transport of multi-species ions in dilute solutions.

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Self-Consistent Approach to Global Charge Neutrality in Electrokinetics: A Surface Potential Trap Model

Cited by 38 publications

References 117 publications

Thin layer analysis of a non-local model for the double layer structure

Thin layer analysis of a non-local model for the double layer structure

Modeling and simulation of dielectrophoretic collective dynamics in a suspension of polarizable particles under the action of a gradient AC electric field

Diffusion Limit of Kinetic Equations for Multiple Species Charged Particles

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