Ion current rectification behavior of a nanochannel having nonuniform cross‐section

Yen, Wei-Kuan; Huang, Wei‐Cheng; Hsu, Jyh‐Ping

doi:10.1002/elps.201900396

Cited by 16 publications

(10 citation statements)

References 54 publications

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“…ICR can be induced by asymmetry in nanopore geometry, as done in conically shaped nanopores, 2 as well as nanopores with stepped cross-section. 12 Asymmetric surface properties of nanopores, e.g. asymmetric charge density, 13 wettability 14 and slip length 15 of surfaces along the pore axis can also produce ICR.…”

Section: Introductionmentioning

confidence: 99%

“…ICR can be induced by asymmetry in the nanopore geometry, as done in conically shaped nanopores, 2 as well as nanopores with a stepped cross section. 12 Asymmetric surface properties of nanopores, for example, asymmetric charge density, 13 wettability, 14 and slip length, 15 of surfaces along the pore axis can also produce ICR. Nanopores in contact with solutions that differed in conductivity achieved by concentration gradients 16 and viscosity gradients 17,18 were reported to exhibit current rectification as well.…”

Section: ■ Introductionmentioning

confidence: 99%

“…One voltage polarity corresponding to the high-conductance state is caused by the accumulation of ions, while the opposite voltage polarity leads to formation of a depletion zone and low ionic conductance. ICR can be induced by asymmetry in the nanopore geometry, as done in conically shaped nanopores, as well as nanopores with a stepped cross section . Asymmetric surface properties of nanopores, for example, asymmetric charge density, wettability, and slip length, of surfaces along the pore axis can also produce ICR.…”

Section: Introductionmentioning

confidence: 99%

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Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores

Yuan

et al. 2020

Anal. Chem.

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Nanopores that exhibit ionic current rectification (ICR) behave like diodes, such that they transport ions more efficiently in one direction than the other. Conical nanopores have been shown to rectify ionic current, but only those with at least 500 nm in length exhibit significant ICR. Here, through the finite element method, we show how ICR of conical nanopores with length below 200 nm can be tuned by controlling individual charged surfaces i.e. inner pore surface (surface inner), and exterior pore surfaces on the tip and base side (surface tip and surface base). The charged surface inner and surface tip can induce obvious ICR individually, while the effects of the charged surface base on ICR can be ignored. The fully charged surface inner alone could render the nanopore counterion-selective and induces significant ion concentration polarization in the tip region, which causes reverse ICR compared to nanopores with all surface charged. In addition, the direction and degree of rectification can be further tuned by the depth of the charged surface inner. When considering the exterior membrane surface only, the charged surface tip causes intra-pore ionic enrichment and depletion under opposite biases which results in significant ICR. Its effective region is within ~40 nm beyond the tip orifice. We also found that individual charged parts of the pore system contributed to ICR in an additive way due to the additive effect on the ion concentration regulation along the pore axis. With various combinations of fully/partially charged surface inner and surface tip , diverse ICR ratios from ~2 to ~170 can be achieved. Our findings shed light on the mechanism of ionic current rectification in ultra-short conical nanopores, and provide a useful guide to the design and modification of ultra-short conical nanopores in ionic circuits and nanofluidic sensors.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores

Yuan

et al. 2020

Anal. Chem.

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“…Due to their capability of simulating versatile charged conditions and responding to environmental changes, biologically inspired artificial nanopores are applied widely in many areas, including ionic current rectification (ICR), − energy conservation, − desalination, − and sensing. − Among these, ICR has been studied extensively in the past decades. This phenomenon refers to the diodelike behavior of a nanopore, where its ionic current–voltage relationship does not follow the conventional Ohm’s rule when the polarity is switched.…”

Section: Introductionmentioning

confidence: 99%

Nanosensing of Acetylcholine Molecules: Influence of the Association Mechanism

Chung

Hsu

2021

Langmuir

Self Cite

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A bullet-shaped nanopore surface modified by two polyelectrolyte (PE) layers, an inner polyethyleneimine (PEI) layer and an outer p-sulfonatocalix[4]-arene (SCX4) layer, is applied to sense trace levels of acetylcholine (Ach) molecules. We show that the higher the order of the association reaction of Ach with SCX4, the smaller the difference between the ionic current when Ach is present and that when it is absent, and so is the difference in the space charge density. In addition, the larger the binding constant K of that reaction, the lower the detection limit but narrower the detection range. Choosing pH 7 is most appropriate because if the pH is low, the concentration polarization of H+ is significant, and as it gets high, both PE layers become uncharged. At pH 7 and K = 2 × 107 L/mol, the detection limit of the nanopore ranges from 1 to 10 nM, which is orders of magnitude lower than that of the other approaches.

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“…For example, the diode-like ion current rectification (ICR) behavior, which assures ions preferentially transporting in one direction and hence amplifies ionic current, can be observed when the symmetry of ionic concentration profiles along the axis of a nanopore is broken [ 18 , 19 ]. Considerable experimental [ 20 , 21 , 22 ] and theoretical [ 23 , 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 ] efforts have been made on ICR in nanofluidics and all these studies concluded that the ICR property only can emerge in case the pore size is comparable to the EDL thickness.…”

Section: Introductionmentioning

confidence: 99%

Improved Rectification and Osmotic Power in Polyelectrolyte-Filled Mesopores

Zheng

Yeh

2020

Micromachines

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Ample studies have shown the use of nanofluidics in the ionic diode and osmotic power generation, but similar ionic devices performed with large-sized mesopores are still poorly understood. In this study, we model and realize the mesoscale ionic diode and osmotic power generator, composed of an asymmetric cone-shaped mesopore with its narrow opening filled with a polyelectrolyte (PE) layer with high space charges. We show that, only when the space charge density of a PE layer is sufficiently large (>1×106 C/m3), the considered mesopore system is able to create an asymmetric ionic distributions in the pore and then rectify ionic current. As a result, the output osmotic power performance can be improved when the filled PE carries sufficiently high space charges. For example, the considered PE-filled mesopore system can show an amplification of the osmotic power of up to 35.1-fold, compared to the bare solid-state mesopore. The findings provide necessary information for the development of large-sized ionic diode and osmotic power harvesting device.

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Ion current rectification behavior of a nanochannel having nonuniform cross‐section

Cited by 16 publications

References 54 publications

Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores

Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores

Nanosensing of Acetylcholine Molecules: Influence of the Association Mechanism

Improved Rectification and Osmotic Power in Polyelectrolyte-Filled Mesopores

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