Literature DB >> 21888368

Origin of giant ionic currents in carbon nanotube channels.

Pei Pang1, Jin He, Jae Hyun Park, Predrag S Krstić, Stuart Lindsay.   

Abstract

Fluid flow inside carbon nanotubes is remarkable: transport of water and gases is nearly frictionless, and the small channel size results in selective transport of ions. Very recently, devices have been fabricated in which one narrow single-walled carbon nanotube spans a barrier separating electrolyte reservoirs. Ion current through these devices is about 2 orders of magnitude larger than predicted from the bulk resistivity of the electrolyte. Electroosmosis can drive these large excess currents if the tube both is charged and transports anions or cations preferentially. By building a nanofluidic field-effect transistor with a gate electrode embedded in the fluid barrier, we show that the tube carries a negative charge and the excess current is carried by cations. The magnitude of the excess current and its control by a gate electrode are correctly predicted by the Poisson-Nernst-Planck-Stokes equations.
© 2011 American Chemical Society

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Year:  2011        PMID: 21888368      PMCID: PMC3563675          DOI: 10.1021/nn202115s

Source DB:  PubMed          Journal:  ACS Nano        ISSN: 1936-0851            Impact factor:   15.881


  21 in total

1.  Field-effect flow control for microfabricated fluidic networks

Authors: 
Journal:  Science       Date:  1999-10-29       Impact factor: 47.728

2.  Coherence resonance in a single-walled carbon nanotube ion channel.

Authors:  Chang Young Lee; Wonjoon Choi; Jae-Hee Han; Michael S Strano
Journal:  Science       Date:  2010-09-10       Impact factor: 47.728

3.  Anomalous ion transport in 2-nm hydrophilic nanochannels.

Authors:  Chuanhua Duan; Arun Majumdar
Journal:  Nat Nanotechnol       Date:  2010-11-28       Impact factor: 39.213

4.  Molecular control of ionic conduction in polymer nanopores.

Authors:  Eduardo R Cruz-Chu; Thorsten Ritz; Zuzanna S Siwy; Klaus Schulten
Journal:  Faraday Discuss       Date:  2009       Impact factor: 4.008

5.  Fast mass transport through sub-2-nanometer carbon nanotubes.

Authors:  Jason K Holt; Hyung Gyu Park; Yinmin Wang; Michael Stadermann; Alexander B Artyukhin; Costas P Grigoropoulos; Aleksandr Noy; Olgica Bakajin
Journal:  Science       Date:  2006-05-19       Impact factor: 47.728

Review 6.  Solid-state nanopores.

Authors:  Cees Dekker
Journal:  Nat Nanotechnol       Date:  2007-03-04       Impact factor: 39.213

Review 7.  Nanopore analytics: sensing of single molecules.

Authors:  Stefan Howorka; Zuzanna Siwy
Journal:  Chem Soc Rev       Date:  2009-06-15       Impact factor: 54.564

8.  Nanogap detector inside nanofluidic channel for fast real-time label-free DNA analysis.

Authors:  Xiaogan Liang; Stephen Y Chou
Journal:  Nano Lett       Date:  2008-04-17       Impact factor: 11.189

9.  Salt dependence of ion transport and DNA translocation through solid-state nanopores.

Authors:  Ralph M M Smeets; Ulrich F Keyser; Diego Krapf; Meng-Yue Wu; Nynke H Dekker; Cees Dekker
Journal:  Nano Lett       Date:  2006-01       Impact factor: 11.189

10.  Translocation of single-stranded DNA through single-walled carbon nanotubes.

Authors:  Haitao Liu; Jin He; Jinyao Tang; Hao Liu; Pei Pang; Di Cao; Predrag Krstic; Sony Joseph; Stuart Lindsay; Colin Nuckolls
Journal:  Science       Date:  2010-01-01       Impact factor: 47.728
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  15 in total

1.  An Electrically Actuated, Carbon-Nanotube-Based Biomimetic Ion Pump.

Authors:  Jake Rabinowitz; Charishma Cohen; Kenneth L Shepard
Journal:  Nano Lett       Date:  2019-12-30       Impact factor: 11.189

2.  Review article: Fabrication of nanofluidic devices.

Authors:  Chuanhua Duan; Wei Wang; Quan Xie
Journal:  Biomicrofluidics       Date:  2013-03-13       Impact factor: 2.800

3.  Molecular transport through capillaries made with atomic-scale precision.

Authors:  B Radha; A Esfandiar; F C Wang; A P Rooney; K Gopinadhan; A Keerthi; A Mishchenko; A Janardanan; P Blake; L Fumagalli; M Lozada-Hidalgo; S Garaj; S J Haigh; I V Grigorieva; H A Wu; A K Geim
Journal:  Nature       Date:  2016-09-07       Impact factor: 49.962

4.  Scaling Behavior of Ionic Transport in Membrane Nanochannels.

Authors:  María Queralt-Martín; M Lidón López; Marcel Aguilella-Arzo; Vicente M Aguilella; Antonio Alcaraz
Journal:  Nano Lett       Date:  2018-09-10       Impact factor: 11.189

5.  DNA translocating through a carbon nanotube can increase ionic current.

Authors:  Jae Hyun Park; Jin He; Brett Gyarfas; Stuart Lindsay; Predrag S Krstić
Journal:  Nanotechnology       Date:  2012-10-22       Impact factor: 3.874

6.  Optical and electrical detection of single-molecule translocation through carbon nanotubes.

Authors:  Weisi Song; Pei Pang; Jin He; Stuart Lindsay
Journal:  ACS Nano       Date:  2012-12-24       Impact factor: 15.881

7.  Mass transport through vertically aligned large diameter MWCNTs embedded in parylene.

Authors:  P Krishnakumar; P B Tiwari; S Staples; T Luo; Y Darici; J He; S M Lindsay
Journal:  Nanotechnology       Date:  2012-10-12       Impact factor: 3.874

8.  Slowing DNA translocation through a nanopore using a functionalized electrode.

Authors:  Padmini Krishnakumar; Brett Gyarfas; Weisi Song; Suman Sen; Peiming Zhang; Predrag Krstić; Stuart Lindsay
Journal:  ACS Nano       Date:  2013-10-29       Impact factor: 15.881

9.  Molecular streaming and its voltage control in ångström-scale channels.

Authors:  T Mouterde; A Keerthi; A R Poggioli; S A Dar; A Siria; A K Geim; L Bocquet; B Radha
Journal:  Nature       Date:  2019-03-06       Impact factor: 49.962

10.  Scaling Behavior for Ionic Transport and its Fluctuations in Individual Carbon Nanotubes.

Authors:  Eleonora Secchi; Antoine Niguès; Laetitia Jubin; Alessandro Siria; Lydéric Bocquet
Journal:  Phys Rev Lett       Date:  2016-04-15       Impact factor: 9.161
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