On Induced Surface Charge in Solid-State Nanopores

Yao, Yao; Wen, Chenyu; Pham, Ngan Hoang; Zhang, Shi-Li

doi:10.1021/acs.langmuir.0c01189

Cited by 32 publications

(41 citation statements)

References 63 publications

(130 reference statements)

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“…Mao et al noted the IC effect in their continuum simulations of nanochannels in a thin silica membrane, but focused primarily on the fluid flow field rather than the I-V characteristics [31]. Further, the role of induced charges has been investigated in terms of membrane stability [32,33] and for conduction through conical nanopores [34]. Based on these previous studies, the IC effect appears especially relevant for membranes in the atomically thin limit.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear ion transport mediated by induced charge in ultrathin nanoporous membranes

et al. 2021

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Ultrathin membranes with nanoporous conduits show promise for ionic separations and desalination applications, but the mechanisms underlying the nonlinear ionic transport observed in these systems are not well understood. Here, we demonstrate how induced charge at membrane interfaces can lead to nonlinear ionic transport and voltage-dependent conductance through such channels. The application of an electric field on a polarizable membrane leads to induced charges at the membrane interfaces. The induced charges in turn are screened by diffuse charges in the electrolyte, which are acted upon by the electric field. For extremely thin membranes, the induced charge effect can be significant even for moderate applied voltages commonly used in experiments. We apply a continuum Poisson-Nernst-Planck model to characterize the current-voltage behavior of ultrathin membranes over a wide parameter space. The predictions of the model are compared to recent experiments on graphene and MoS 2 membranes in an electric field. We expect the role of induced charge to be especially pronounced in the limit of atomically thin membranes.

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Section: Introductionmentioning

confidence: 99%

Nonlinear ion transport mediated by induced charge in ultrathin nanoporous membranes

et al. 2021

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“…The slight non-linear I-V characteristics result from the asymmetric pore geometry and the inhomogeneous surface charge distribution. The latter is mainly generated by the ISC effect 31 , especially near the tip of the smallest restriction of the BNP.…”

Section: Fabrication and Characterisation Of Bnpsmentioning

confidence: 99%

“…This invariance in position and ow direction of the vortexes after reversing the polarity of external bias is of signi cant implications for DNA translocation shown below. The root cause for the intriguing vortex formation is the surface charge imparity primarily due to the effect of ISC 31 near the smallest restriction where the membrane remains ultrathin for an extended stretch (Fig. S1b, S2 in Supporting Information).…”

Section: Theory Of Bnpsmentioning

confidence: 99%

Nanopore design for exceptional rectification of DNA translocation

Pham¹,

Yao²,

Wen³

et al. 2021

Preprint

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Solid-state nanopores (SSNPs) of on-demand shape and size can facilitate desired sensor performance. However, reproducible production of arrayed nanopores of predefined geometry is yet to demonstrate despite of numerous methods explored. Here, bowl-shape SSNPs combining unique properties of ultrathin membrane and tapering geometry are demonstrated. The bowl-SSNP upper opening is 100-120 nm in diameter, with the bottom opening reaching sub-5 nm. Numerical simulation reveals the formation of multiple electroosmotic vortexes (EOVs) originating from distributed surface charge around the pore-bowl. The EOVs determine, collaboratively with electrophoretic force, how nanoscale objects translocate the bowl-SSNPs. Exceptional rectification with higher frequencies, longer duration and larger amplitude is found when DNA strands translocate downwards from the upper large opening than upwards from the bottom smallest restriction. The rectification is a manifestation of the interplay between electrophoresis and electroosmosis. The resourceful silicon nanofabrication technology is ingeniously shown to enable innovative nanopore designs targeting unprecedented sensor applications.

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“…The tangential component of the electric field at the wall, E t , moves the accumulated charges. h) Continuum simulation results for a negatively charged truncated-conical nanopore [30], showing the distribution of the net charge concentration and corresponding electroosmotic velocity field at negative bias ∆V = −5 V. i) Induced charge selectivity and EOF in an uncharged cylindrical nanopore [31], exploiting symmetry breaking due to a lateral cavity surrounding the nanopore. The simultaneous inversion of ionic selectivity and electric field direction causes a unidirectional parabolic EOF.…”

Section: Electroosmosis Working Principlementioning

confidence: 99%

Electroosmosis in nanopores: Computational methods and technological applications

Gubbiotti¹,

Baldelli²,

Muccio³

et al. 2021

Preprint

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Electroosmosis is a fascinating effect where liquid motion is induced by an applied electric field. Counter ions accumulate in the vicinity of charged surfaces, triggering a coupling between liquid mass transport and external electric field. In nanofluidic technologies, where surfaces play an exacerbated role, electroosmosis is thus of primary importance. Its consequences on the transport properties in biological and synthetic nanopores are subtle and intricate. Thorough understanding is therefore challenging yet crucial to fully assess the mechanisms at play. Here, we review recent progress on computational techniques for the analysis of electroosmosis and discuss technological applications, in particular for sensing devices.

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On Induced Surface Charge in Solid-State Nanopores

Cited by 32 publications

References 63 publications

Nonlinear ion transport mediated by induced charge in ultrathin nanoporous membranes

Nonlinear ion transport mediated by induced charge in ultrathin nanoporous membranes

Nanopore design for exceptional rectification of DNA translocation

Electroosmosis in nanopores: Computational methods and technological applications

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