Nonlinear dynamics of ion concentration polarization in porous media: The leaky membrane model

Dydek, E. Victoria; Bazant, Martin Z.

doi:10.1002/aic.14200

Cited by 77 publications

(132 citation statements)

References 86 publications

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“…In microsystems, surface effects are comparatively important, and for this reason their behavior is fundamentally different from bulk systems. For instance, an entirely new mode of overlimiting current enabled by surface conduction, has been predicted by Dydek et al [26,27], for which the current exceeding the diffusion-limited current runs through the depletion region inside the diffuse double layers screening the surface charges. This gives rise to an overlimiting current depending linearly on the surface charge, the surface-to-bulk ratio, and the applied potential.…”

Section: Introductionmentioning

confidence: 99%

Concentration polarization, surface currents, and bulk advection in a microchannel

Nielsen

Bruus

2014

Phys. Rev. E

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We present a comprehensive analysis of salt transport and overlimiting currents in a microchannel during concentration polarization. We have carried out full numerical simulations of the coupled Poisson-Nernst-Planck-Stokes problem governing the transport and rationalized the behaviour of the system. A remarkable outcome of the investigations is the discovery of strong couplings between bulk advection and the surface current; without a surface current, bulk advection is strongly suppressed. The numerical simulations are supplemented by analytical models valid in the long channel limit as well as in the limit of negligible surface charge. By including the effects of diffusion and advection in the diffuse part of the electric double layers, we extend a recently published analytical model of overlimiting current due to surface conduction.

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Section: Introductionmentioning

confidence: 99%

Concentration polarization, surface currents, and bulk advection in a microchannel

Nielsen

Bruus

2014

Phys. Rev. E

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“…It is well known that interfaces between charged membranes or nanochannels and unsupported bulk electrolytes lead to ion concentration polarization outside the membrane, e.g., in classical electrodialysis [33][34][35], but complex nonequilibrium electrokinetic phenomena resulting from strong concentration polarization have recently been discovered inside membrane pores or microchannels, such as deionization shock waves [32,[36][37][38][39][40][41] and overlimiting current sustained by surface conduction (electromigration) and electro-osmotic flow [42][43][44][45] with applications to nanotemplated electrodeposition [46] and water desalination by "shock electrodialysis" [47]. In most situations for nanochannels, the ions remain in local quasiequilibrium, since electromigration FIG.…”

Section: Introductionmentioning

confidence: 99%

Analysis of electrolyte transport through charged nanopores

et al. 2016

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We revisit the classical problem of flow of electrolyte solutions through charged capillary nanopores or nanotubes as described by the capillary pore model (also called "space charge" theory). This theory assumes very long and thin pores and uses a one-dimensional flux-force formalism which relates fluxes (electrical current, salt flux, and fluid velocity) and driving forces (difference in electric potential, salt concentration, and pressure). We analyze the general case with overlapping electric double layers in the pore and a nonzero axial salt concentration gradient. The 3×3 matrix relating these quantities exhibits Onsager symmetry and we report a significant new simplification for the diagonal element relating axial salt flux to the gradient in chemical potential. We prove that Onsager symmetry is preserved under changes of variables, which we illustrate by transformation to a different flux-force matrix given by Gross and Osterle [J. Chem. Phys. 49, 228 (1968)]. The capillary pore model is well suited to describe the nonlinear response of charged membranes or nanofluidic devices for electrokinetic energy conversion and water desalination, as long as the transverse ion profiles remain in local quasiequilibrium. As an example, we evaluate electrical power production from a salt concentration difference by reverse electrodialysis, using an efficiency versus power diagram. We show that since the capillary pore model allows for axial gradients in salt concentration, partial loops in current, salt flux, or fluid flow can develop in the pore. Predictions for macroscopic transport properties using a reduced model, where the potential and concentration are assumed to be invariant with radial coordinate ("uniform potential" or "fine capillary pore" model), are close to results of the full model.

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“…Finally, the electroconvection becomes very strong and unstable in case of the 22 μm deep microchannel, but still occurs behind the shock away from the membrane surface. Although this unstable flow resembles the bulk behavior [6,13,[28][29][30], the channel is not nearly thick enough to see the Rubinstein-Zaltzman electroosmotic instability, which originates on the membrane and is predicted to dominate only above 400 μm depth [31].…”

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confidence: 99%

“…(6) The salt concentration tends to form very sharp gradients between the depleted and concentrated regions (on the anodic, depleted side of the membrane), perhaps first observed a decade ago [25]. In micronanofluidic device in which steady over-limiting current has been observed [26], salt gradients propagate as shock waves, [6,27] or "deionization shocks" [28][29][30] at constant current, due to the nonlinear effect of ion transport in the electric double layers of the sidewalls. These observations suggest that multiple transport mechanisms may be involved when overlimiting current occurs under strong confinement.…”

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confidence: 99%

“…The details of the changes can be found in the videos in the Supplemental Material [39] for each depth. At 2 μm depth, a flat depletion zone propagates as a deionization shock wave from the nanojunction over the microchannel [6,25,[27][28][29][30], and the strong vortical motions are largely suppressed and hardly observed because of geometrical constrictions [19,26]. Transverse diffusion of the dye across the depth also eliminates concentration gradients [31,34].…”

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confidence: 99%

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Experimental Verification of Overlimiting Current by Surface Conduction and Electro-Osmotic Flow in Microchannels

et al. 2015

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Direct evidence is provided for the transition from surface conduction (SC) to electro-osmotic flow (EOF) above a critical channel depth (d) of a nanofluidic device. The dependence of the overlimiting conductance (OLC) on d is consistent with theoretical predictions, scaling as d −1 for SC and d 4=5 for EOF with a minimum around d ¼ 8 μm. The propagation of transient deionization shocks is also visualized, revealing complex patterns of EOF vortices and unstable convection with increasing d. This unified picture of surface-driven OLC can guide further advances in electrokinetic theory, as well as engineering applications of ion concentration polarization in microfluidics and porous media.

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Nonlinear dynamics of ion concentration polarization in porous media: The leaky membrane model

Cited by 77 publications

References 86 publications

Concentration polarization, surface currents, and bulk advection in a microchannel

Concentration polarization, surface currents, and bulk advection in a microchannel

Analysis of electrolyte transport through charged nanopores

Experimental Verification of Overlimiting Current by Surface Conduction and Electro-Osmotic Flow in Microchannels

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