Electric Field-Responsive Nanopores with Ion Selectivity: Controlling Based on Transport Resistance

Yudan Zhu; Yang Ruan; Ximing Wu; Xiaohua Lu; Yumeng Zhang; Linghong Lu

doi:10.1002/ceat.201500637

Electric Field-Responsive Nanopores with Ion Selectivity: Controlling Based on Transport Resistance

Yudan Zhu, Yang Ruan, Ximing Wu, Xiaohua Lu, Yumeng Zhang, Linghong Lu

College of Chemical Engineering

Nanjing Tech University

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Using external stimuli to control ionic transport behavior in nanopores is an important focus of nanodevice research allowing numerous potential applications. A novel strategy was investigated to control ionic-transport resistance responses to the electric field intensity in a nanopore and regulate ionic selectivity. Molecular simulations were performed to examine the transport behaviors of K⁺ and Na⁺ in a carbon nanotube-based biomimetic nanopore under different electric fields. The responses of the modified group to the electric field intensity induced variations in ionic transport resistance, which then led to improved ionic selectivity. This result indicates that driving force and resistance are simultaneously affected by external stimuli under nanoconfinement.

Original language	English
Pages (from-to)	993-997
Number of pages	5
Journal	Chemical Engineering and Technology
Volume	39
Issue number	5
DOIs	https://doi.org/10.1002/ceat.201500637
State	Published - 1 May 2016

Keywords

Electric field-responsive nanopores
Ion selectivity
Molecular simulation
Nanochannels
Transport resistance

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10.1002/ceat.201500637

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abstract = "Using external stimuli to control ionic transport behavior in nanopores is an important focus of nanodevice research allowing numerous potential applications. A novel strategy was investigated to control ionic-transport resistance responses to the electric field intensity in a nanopore and regulate ionic selectivity. Molecular simulations were performed to examine the transport behaviors of K+ and Na+ in a carbon nanotube-based biomimetic nanopore under different electric fields. The responses of the modified group to the electric field intensity induced variations in ionic transport resistance, which then led to improved ionic selectivity. This result indicates that driving force and resistance are simultaneously affected by external stimuli under nanoconfinement.",

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T1 - Electric Field-Responsive Nanopores with Ion Selectivity

T2 - Controlling Based on Transport Resistance

AU - Zhu, Yudan

AU - Ruan, Yang

AU - Wu, Ximing

AU - Lu, Xiaohua

AU - Zhang, Yumeng

AU - Lu, Linghong

PY - 2016/5/1

Y1 - 2016/5/1

N2 - Using external stimuli to control ionic transport behavior in nanopores is an important focus of nanodevice research allowing numerous potential applications. A novel strategy was investigated to control ionic-transport resistance responses to the electric field intensity in a nanopore and regulate ionic selectivity. Molecular simulations were performed to examine the transport behaviors of K+ and Na+ in a carbon nanotube-based biomimetic nanopore under different electric fields. The responses of the modified group to the electric field intensity induced variations in ionic transport resistance, which then led to improved ionic selectivity. This result indicates that driving force and resistance are simultaneously affected by external stimuli under nanoconfinement.

AB - Using external stimuli to control ionic transport behavior in nanopores is an important focus of nanodevice research allowing numerous potential applications. A novel strategy was investigated to control ionic-transport resistance responses to the electric field intensity in a nanopore and regulate ionic selectivity. Molecular simulations were performed to examine the transport behaviors of K+ and Na+ in a carbon nanotube-based biomimetic nanopore under different electric fields. The responses of the modified group to the electric field intensity induced variations in ionic transport resistance, which then led to improved ionic selectivity. This result indicates that driving force and resistance are simultaneously affected by external stimuli under nanoconfinement.

KW - Electric field-responsive nanopores

KW - Ion selectivity

KW - Molecular simulation

KW - Nanochannels

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Electric Field-Responsive Nanopores with Ion Selectivity: Controlling Based on Transport Resistance

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Keywords

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