Ionic Current Behaviors of Dual Nano- and Micropipettes

Zhang, Shudong; Yin, Xiaohong; Li, Mingzhi; Zhang, Xianhao; Zhang, Xin; Zhu, Zhiwei; Yang, Shuang; Shao, Yuanhua

doi:10.1021/acs.analchem.8b01765

Cited by 21 publications

(24 citation statements)

References 71 publications

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“…However, the effect of gas phase on the ion transfer can hardly be probed based on such structure. Theta pipettes have previously been used to study ion mass transfer through a liquid–liquid interface. − When the theta micropipette is exposed to the air, the ion mass transfer through the two barrels can be modulated by the gas phase. However, such ion mass transfer is unstable due to the uncontrollable evaporation of the meniscus solvent that cover both orifices of the theta micropipette.…”

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confidence: 99%

Mass Transfer Modulation and Gas Mapping Based on Covalent Organic Frameworks-Covered Theta Micropipette

et al. 2020

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Covalent organic frameworks (COFs) consist nanochannels that are fundamentally important for their application. Up to now, the effect of gas phase on COF nanochannels are hard to explore. Here, TAPB-PDA-COFs (triphenylbenzene-terephthaldehyde-COFs) was synthesized in situ at the tip of a theta micropipette. The COF-covered theta micropipette (CTP) create a stable gas−liquid interface inside the COF nanochannels, through which the humidity-modulated ion mass transfer in the COF nanochannels can be recorded by recording the current across the two channels of the theta micropipette. Results show that the humid air changes the mobility of the ions inside the COF nanochannels, which leads to the change of ionic current. Humid air showed different effects on the ion transfer depending on the solvent polarity index and vapor pressure. Current decreases linearly with the increase of relative humidity (RH) from 11% to 98%. The CTP was also mounted on the scanning electrochemical microscopy as a probe electrode for mapping micrometer-scale humidity distribution.

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confidence: 99%

Mass Transfer Modulation and Gas Mapping Based on Covalent Organic Frameworks-Covered Theta Micropipette

et al. 2020

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“…Ion transport in a fluidic channel has been intensively studied for promising applications including energy harvesters, − iontronics, − artificial neurons, and single-molecule sensing. , It implements electric field-driven ion and mass transport in a confined space, wherein electrostatics and fluid dynamics reflect rich properties of the wall surface to induce pronounced ion selectivity and the associated unique ionic current characteristics that cannot be expected in bulk systems. According to this principle, nanofluidic devices demonstrated a variety of ion transport properties such as ionic current rectification (ICR) and negative differential resistance (NDR) , via geometric structure engineering, membrane material designs, , and molecular functionalizations ,− to provide high-density surface charge to the walls and increase the surface-to-volume ratio of fluidic channels. The surface effects were, however, known to be effective only in a small channel of sub-Debye length size because of screening of the electrostatic field at the wall by the electrolyte ions.…”

Section: Introductionmentioning

confidence: 99%

Quasi-Stable Salt Gradient and Resistive Switching in Solid-State Nanopores

Leong

Tsutsui

Murayama

et al. 2020

ACS Appl. Mater. Interfaces

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Understanding and control of ion transport in a fluidic channel is of crucial importance for iontronics. The present study reports on quasi-stable ionic current characteristics in a SiNx nanopore under a salinity gradient. An intriguing interplay between electro-osmotic flow and local ion density distributions in a solid-state pore is found to induce highly asymmetric ion transport to negative differential resistance behavior under a 100-fold difference in the cross-membrane salt concentrations. Meanwhile, a subtle change in the salinity gradient profile led to observations of resistive switching. This peculiar characteristic was suggested to stem from quasi-stable local ion density around the channel that can be switched between two distinct states via the electro-osmotic flow under voltage control. The present findings may be useful for neuromorphic devices based on micro- and nanofluidic channels.

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“…Ion transport in fluidic channels has been extensively studied for ionic electronics − and energy harvest. − Functional nanochannels with various ion transport properties have been reported, such as artificial ion channel, rectification, negative differential resistance, and even memristive switching . In general, surface charge effects play a central role on rendering the unique characteristics through the electrostatic interactions with mobile electrolyte ions in the sub-Debye length scale conduits with overlapped electric double layers. , This in turn predicts function-less fluidic devices with characteristic sizes much larger than a screening length, as the ion conductivity will largely be determined by the bulk properties.…”

Section: Introductionmentioning

confidence: 99%

Electroosmosis-Driven Nanofluidic Diodes

et al. 2020

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Fundamental understanding of ion transport in a fluidic channel is of critical importance for realizing iontronics. Here we report on asymmetric ion transport in a low thickness-to-diameter aspect ratio nanopore. Under uniform salt concentration conditions, the cross-pore ionic current showed ohmic characteristics with no bias polarity dependence. In stark contrast, despite the weak ion selectivity expected for the relatively large nanopores employed, we observed diode-like behavior when a salt gradient was imposed across the thin membrane. This unexpected result was attributed to the electroosmotic flow that served to modulate the access resistance through dragging the condensed ions into or out of the nanopore orifices. The simple mechanism was also revealed to be effective in fluidic channels of various size from micro- to nanoscale enabling rectification of the property engineering by the pore geometries. The present findings allow for novel designs of artificial ion channel building blocks.

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Ionic Current Behaviors of Dual Nano- and Micropipettes

Cited by 21 publications

References 71 publications

Mass Transfer Modulation and Gas Mapping Based on Covalent Organic Frameworks-Covered Theta Micropipette

Mass Transfer Modulation and Gas Mapping Based on Covalent Organic Frameworks-Covered Theta Micropipette

Quasi-Stable Salt Gradient and Resistive Switching in Solid-State Nanopores

Electroosmosis-Driven Nanofluidic Diodes

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