High‐Performance Integrated Iontronic Circuits Based on Single Nano/Microchannels

Li, Jun; Li, Mengqi; Zhang, Kaiping; Hu, Lide; Li, Dongqing

doi:10.1002/smll.202208079

Cited by 4 publications

(2 citation statements)

References 53 publications

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“…As building blocks, the ionic diodes open up the possibilities in the development of functionalized iontronic systems. Our group constructed a bipolar junction transistor by assembling two back‐to‐back diodes in a fluidic chip [80]. The chip performs as an NPN‐type transistor with the output current between the terminals of source and drain controlled by the gate.…”

Section: Applications Of Electrokinetic Nanofluidicsmentioning

confidence: 99%

Electrokinetic transport phenomena in nanofluidics and their applications

Sun

Jiang

et al. 2023

Electrophoresis

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Much progress has been made in the electrokinetic phenomena inside nanochannels in the last decades. As the dimensions of the nanochannels are compatible to that of the electric double layer (EDL), the electrokinetics inside nanochannels indicate many unexpected behaviors, which show great potential in the fields of material science, biology, and chemistry. This review summarizes the recent development of nanofluidic electrokinetics in both fundamental and applied research. First, the techniques for constructing nanochannels are introduced to give a guideline for choosing the optimal fabrication technique based on the specific feature of the nanochannel. Then, the theories and experimental investigations of the EDL, electroosmotic flow, and electrophoresis of nanoparticles inside the nanochannels are discussed. Furthermore, the applications of nanofluidic electrokinetics in iontronics, sensing, and biomolecule separation fields are summarized. In Section 5, some critical challenges and the perspective on the future development of nanofluidic electrokinetics are briefly proposed.

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Section: Applications Of Electrokinetic Nanofluidicsmentioning

confidence: 99%

Electrokinetic transport phenomena in nanofluidics and their applications

Sun

Jiang

et al. 2023

Electrophoresis

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“…Field-effect control of electron transport constitutes a fundamental process in semiconductor technologies, laying the groundwork for von Neumann-type computing. In parallel to solid-state electronics, there has been significant research into the study of ion transport through fluidic channels, with the goal of demonstrating electronic component functionalities based on ionic current characteristics. − Recent advancements in this emerging field of iontronics have unveiled a wealth of properties in nanochannels, ranging from diodes to memristors, − primarily attributable to the profound influence of surface interactions on fluid and ion transport. − …”

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confidence: 99%

Gate-All-Around Nanopore Osmotic Power Generators

Tsutsui,

Hsu,

Garoli

et al. 2024

ACS Nano

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Nanofluidic channels in a membrane represent a promising avenue for harnessing blue energy from salinity gradients, relying on permselectivity as a pivotal characteristic crucial for inducing electricity through diffusive ion transport. Surface charge emerges as a central player in the osmotic energy conversion process, emphasizing the critical significance of a judicious selection of membrane materials to achieve optimal ion permeability and selectivity within specific channel dimensions. Alternatively, here we report a field-effect approach for in situ manipulation of the ion selectivity in a nanopore. Application of voltage to a surround-gate electrode allows precise adjustment of the surface charge density at the pore wall. Leveraging the gating control, we demonstrate permselectivity turnover to enhanced cation selective transport in multipore membranes, resulting in a 6-fold increase in the energy conversion efficiency with a power density of 15 W/m 2 under a salinity gradient. These findings not only advance our fundamental understanding of ion transport in nanochannels but also provide a scalable and efficient strategy for nanoporous membrane osmotic power generation.

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Brain-inspired computing with fluidic iontronic nanochannels

Kamsma,

Kim,

Kim

et al. 2024

Proc. Natl. Acad. Sci. U.S.A.

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The brain’s remarkable and efficient information processing capability is driving research into brain-inspired (neuromorphic) computing paradigms. Artificial aqueous ion channels are emerging as an exciting platform for neuromorphic computing, representing a departure from conventional solid-state devices by directly mimicking the brain’s fluidic ion transport. Supported by a quantitative theoretical model, we present easy-to-fabricate tapered microchannels that embed a conducting network of fluidic nanochannels between a colloidal structure. Due to transient salt concentration polarization, our devices are volatile memristors (memory resistors) that are remarkably stable. The voltage-driven net salt flux and accumulation, that underpin the concentration polarization, surprisingly combine into a diffusionlike quadratic dependence of the memory retention time on the channel length, allowing channel design for a specific timescale. We implement our device as a synaptic element for neuromorphic reservoir computing. Individual channels distinguish various time series, that together represent (handwritten) numbers, for subsequent in silico classification with a simple readout function. Our results represent a significant step toward realizing the promise of fluidic ion channels as a platform to emulate the rich aqueous dynamics of the brain.

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High‐Performance Integrated Iontronic Circuits Based on Single Nano/Microchannels

Cited by 4 publications

References 53 publications

Electrokinetic transport phenomena in nanofluidics and their applications

Electrokinetic transport phenomena in nanofluidics and their applications

Gate-All-Around Nanopore Osmotic Power Generators

Brain-inspired computing with fluidic iontronic nanochannels

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