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Tunable Ionic Transport Control inside a Bio‐Inspired Constructive Bi‐Channel Nanofluidic Device

Inspired by the cooperative functions of the asymmetrical ion channels in living cells, a constructive bi‐channel nanofluidic device that demonstrates the enhanced capability of multiple regulations over both the ion flux amount and the ionic rectification property is prepared. In this bi‐channel sy... Full description

Journal Title: Small February 2014, Vol.10(4), pp.793-801
Main Author: Zeng, Lu
Other Authors: Yang, Zhe , Zhang, Huacheng , Hou, Xu , Tian, Ye , Yang, Fu , Zhou, Jianjun , Li, Lin , Jiang, Lei
Format: Electronic Article Electronic Article
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ID: ISSN: 1613-6810 ; E-ISSN: 1613-6829 ; DOI: 10.1002/smll.201301647
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recordid: wj10.1002/smll.201301647
title: Tunable Ionic Transport Control inside a Bio‐Inspired Constructive Bi‐Channel Nanofluidic Device
format: Article
creator:
  • Zeng, Lu
  • Yang, Zhe
  • Zhang, Huacheng
  • Hou, Xu
  • Tian, Ye
  • Yang, Fu
  • Zhou, Jianjun
  • Li, Lin
  • Jiang, Lei
subjects:
  • Bio‐Inspired
  • Bi‐Channel
  • Cooperative Functions
  • Ionic Transport
  • Nanofluidic Devices
ispartof: Small, February 2014, Vol.10(4), pp.793-801
description: Inspired by the cooperative functions of the asymmetrical ion channels in living cells, a constructive bi‐channel nanofluidic device that demonstrates the enhanced capability of multiple regulations over both the ion flux amount and the ionic rectification property is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes. In addition, the variation of external pH conditions leads the nanodevice to the uncharged, semi‐charged and charged states, where the multistory ionic regulating function property is enhanced by the charged degree. This intelligent integration of the single functional nanochannels demonstrates a promising future for building more functional multi‐channel integrated nanodevices as well as expands the functionalities of the bio‐inspired smart nanochannels. is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes, where the multistory ionic regulating property is further enhanced by the charged degree.
language:
source:
identifier: ISSN: 1613-6810 ; E-ISSN: 1613-6829 ; DOI: 10.1002/smll.201301647
fulltext: fulltext
issn:
  • 1613-6810
  • 16136810
  • 1613-6829
  • 16136829
url: Link


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titleTunable Ionic Transport Control inside a Bio‐Inspired Constructive Bi‐Channel Nanofluidic Device
creatorZeng, Lu ; Yang, Zhe ; Zhang, Huacheng ; Hou, Xu ; Tian, Ye ; Yang, Fu ; Zhou, Jianjun ; Li, Lin ; Jiang, Lei
ispartofSmall, February 2014, Vol.10(4), pp.793-801
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subjectBio‐Inspired ; Bi‐Channel ; Cooperative Functions ; Ionic Transport ; Nanofluidic Devices
descriptionInspired by the cooperative functions of the asymmetrical ion channels in living cells, a constructive bi‐channel nanofluidic device that demonstrates the enhanced capability of multiple regulations over both the ion flux amount and the ionic rectification property is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes. In addition, the variation of external pH conditions leads the nanodevice to the uncharged, semi‐charged and charged states, where the multistory ionic regulating function property is enhanced by the charged degree. This intelligent integration of the single functional nanochannels demonstrates a promising future for building more functional multi‐channel integrated nanodevices as well as expands the functionalities of the bio‐inspired smart nanochannels. is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes, where the multistory ionic regulating property is further enhanced by the charged degree.
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titleTunable Ionic Transport Control inside a Bio‐Inspired Constructive Bi‐Channel Nanofluidic Device
descriptionInspired by the cooperative functions of the asymmetrical ion channels in living cells, a constructive bi‐channel nanofluidic device that demonstrates the enhanced capability of multiple regulations over both the ion flux amount and the ionic rectification property is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes. In addition, the variation of external pH conditions leads the nanodevice to the uncharged, semi‐charged and charged states, where the multistory ionic regulating function property is enhanced by the charged degree. This intelligent integration of the single functional nanochannels demonstrates a promising future for building more functional multi‐channel integrated nanodevices as well as expands the functionalities of the bio‐inspired smart nanochannels. is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes, where the multistory ionic regulating property is further enhanced by the charged degree.
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abstractInspired by the cooperative functions of the asymmetrical ion channels in living cells, a constructive bi‐channel nanofluidic device that demonstrates the enhanced capability of multiple regulations over both the ion flux amount and the ionic rectification property is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes. In addition, the variation of external pH conditions leads the nanodevice to the uncharged, semi‐charged and charged states, where the multistory ionic regulating function property is enhanced by the charged degree. This intelligent integration of the single functional nanochannels demonstrates a promising future for building more functional multi‐channel integrated nanodevices as well as expands the functionalities of the bio‐inspired smart nanochannels. is prepared. In this bi‐channel system, the construction routes of the two asymmetric conical nanochannels provide a way to efficiently transform the nanodevice into four different functional working modes, where the multistory ionic regulating property is further enhanced by the charged degree.
doi10.1002/smll.201301647
pages793-801
date2014-02