Bioinspired Solid‐State Ion Nanochannels: Insight from Channel Fabrication and Ion Transport

Yun, Zhang; Chen, Duo; Wang, He; Tan, Jie; Yang, Yanbing; Yuan, Quan

doi:10.1002/admt.202202014

Adv Materials Technologies

2023

DOI: 10.1002/admt.202202014

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Bioinspired Solid‐State Ion Nanochannels: Insight from Channel Fabrication and Ion Transport

Zhang Yun

Duo Chen

He Wang

et al.

Abstract: With specific structures and unique features, biological ion channel proteins play crucial roles in many life processes of living organisms. Inspired by the biological ion channel proteins, researchers have developed a variety of artificial nanochannels to explore the mechanisms of selective ion transport and achieve applications in molecular filters, biosensors, and energy conversion devices. The ion transport behavior in nanochannels is mainly governed by the interaction between ions and the nanochannels int… Show more

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Cited by 3 publications

References 260 publications

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Biomimetic Channels Design in Metal‐Organic Framework Enabling Highly Lithium‐Ion Conduction for Lithium‐Metal Batteries

Wang,

Jin,

Shi

et al. 2024

Small Methods

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Solid‐state electrolytes (SSEs) based on metal‐organic frameworks (MOFs) are an ideal material for constructing high‐performance lithium metal batteries (LMBs). However, the low ion conductivity and poor interface contact (especially at low temperatures) still seriously hinder its further application. Herein, inspired by the Na+/K+ conduction in biology systems, a series (NH2, OH, NH‐(CH2)3‐SO3H)‐modified MIL‐53‐X as SSEs is reported. These functional groups are similar to anions suspended in biological ion channels, partially repelling anions while allowing cations to be effectively transported through pore channels. Subsequently, MIL‐53‐X with hierarchical pore structure (H‐MIL‐53‐X) is obtained by introducing lauric acid as a regulator, and then the effects of structural design and morphology control on its performance are explored. The conductivity of H‐MIL‐53‐NH‐SO3Li with multi‐level pore structure and modified by sulfonic acid groups reached 2.2 × 10−3 S cm−1 at 25 °C, lithium‐ion transference number of 0.78. Besides, the H‐MIL‐53‐NH‐SO3Li still has an excellent conductivity of 10−4 S cm−1 at −40 °C. Additionally, LiFePO4/Li batteries equipped with H‐MIL‐53‐NH‐SO3Li SSEs could operate stably for over 200 cycles at 0.1 C. The strategy of combining structural and morphological design of MOFs with biomimetic ion channels opens new avenues for the design of high‐performance SSEs.

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Biomimetic Channels Design in Metal‐Organic Framework Enabling Highly Lithium‐Ion Conduction for Lithium‐Metal Batteries

Wang,

Jin,

Shi

et al. 2024

Small Methods

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Illuminating Biomimetic Nanochannels: Unveiling Macroscopic Anticounterfeiting and Photoswitchable Ion Conductivity via Polymer Tailoring

Chen,

Pruthi,

Lee

et al. 2024

ACS Nano

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Artificial photomodulated channels represent a significant advancement toward practical photogated systems because of their remote noncontact stimulation. Ion transport behaviors in artificial photomodulated channels, however, still require further investigation, especially in multiple nanochannels that closely resemble biological structures. Herein, we present the design and development of photoswitchable ion nanochannels inspired by natural channelrhodopsins (ChRs), utilizing photoresponsive polymers grafted anodic aluminum oxide (AAO) membranes. Our approach integrates spiropyran (SP) as photoresponsive molecules into nanochannels through surface-initiated atom transfer radical polymerization (SI-ATRP), creating a responsive system that modulates ionic conductivity and hydrophilicity in response to light stimuli. A key design feature is the reversible ring-opening photoisomerization of spiropyran groups under UV irradiation. This transformation, observable at the molecular level and macroscopically, allows the surface inside the nanochannels to switch between hydrophobic and hydrophilic states, thus efficiently modulating ion transport via changing water wetting behaviors. The patternable and erasable polySP-grafted AAO, based on a controllable and reversible photochromic effect, also shows potential applications in anticounterfeiting. This study pioneers achieving macroscopic anticounterfeiting and photoinduced photoswitching through reversible surface chemistry and expands the application of polymer-grafted structures in multiple nanochannels.

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Principles of Biomimetic solid-state nanopores and the application to biosensors

Tang

2023

HSET

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The wide application of biomimetic solid-state nanopores in biosensors has made them a high-profile research area. It can be applied in several fields such as genomics, proteomics, biomedicine, and environmental monitoring. Bionic solid-state nanopores have demonstrated the capability to detect biomolecules and creatures, including proteins, nucleic acids, cells, and microbes, with a notable degree of sensitivity and selectivity. Biomimetic solid-state nanopores offer several advantages over conventional biosensors. An innovative kind of biosensor is called biomimetic solid state nanopores. This study provides a comprehensive overview of the principle, construction, and use of the bionic solid state nanopore sensor. Bionic solid-state nanopores are of significant importance within the realm of biosensors. Firstly, it has micrometer or nanometer scale, which can effectively capture and control target molecules; Additionally, the dimensions of the biomimetic solid-state nanopores can be modified, along with the surface functionalization, in order to enhance the performance of the sensor and expand its potential applications. In addition, the structural stability and reusability of biomimetic solid-state nanopores also guarantee the long-term application of biosensors. Through in-depth research and development, it is expected to promote the technological progress in the field of biosensors, and provide more accurate and reliable detection methods for life science, medical diagnosis, environmental protection and other fields.

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Bioinspired Solid‐State Ion Nanochannels: Insight from Channel Fabrication and Ion Transport

Cited by 3 publications

References 260 publications

Biomimetic Channels Design in Metal‐Organic Framework Enabling Highly Lithium‐Ion Conduction for Lithium‐Metal Batteries

Biomimetic Channels Design in Metal‐Organic Framework Enabling Highly Lithium‐Ion Conduction for Lithium‐Metal Batteries

Illuminating Biomimetic Nanochannels: Unveiling Macroscopic Anticounterfeiting and Photoswitchable Ion Conductivity via Polymer Tailoring

Principles of Biomimetic solid-state nanopores and the application to biosensors

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