Origin of giant ionic currents in carbon nanotube channels.

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.

[1]  R. Schasfoort,et al.  Field-effect flow control for microfabricated fluidic networks , 1999, Science.

[2]  N. Aluru,et al.  Atypical Dependence of Electroosmotic Transport on Surface Charge in a Single-wall Carbon Nanotube , 2003 .

[3]  N. Aluru,et al.  Ion separation using a Y-junction carbon nanotube , 2005 .

[4]  A. Majumdar,et al.  Electrostatic control of ions and molecules in nanofluidic transistors. , 2005, Nano letters.

[5]  Mainak Majumder,et al.  Nanoscale hydrodynamics: Enhanced flow in carbon nanotubes , 2005, Nature.

[6]  C. Grigoropoulos,et al.  Fast Mass Transport Through Sub-2-Nanometer Carbon Nanotubes , 2006, Science.

[7]  U. Keyser,et al.  Salt dependence of ion transport and DNA translocation through solid-state nanopores. , 2006, Nano letters.

[8]  C. Dekker Solid-state nanopores. , 2007, Nature nanotechnology.

[9]  Wei Yang Lu,et al.  Near-static dielectric polarization of individual carbon nanotubes. , 2007, Nano letters.

[10]  Sony Joseph,et al.  Why are carbon nanotubes fast transporters of water? , 2008, Nano letters.

[11]  P. Renaud,et al.  Transport phenomena in nanofluidics , 2008 .

[12]  S. Chou,et al.  Nanogap detector inside nanofluidic channel for fast real-time label-free DNA analysis. , 2008, Nano letters.

[13]  Zhonghua Ni,et al.  Electroosmotic flow in nanotubes with high surface charge densities. , 2008, Nano letters.

[14]  J. Eijkel,et al.  Principles and applications of nanofluidic transport. , 2009, Nature nanotechnology.

[15]  Sung-Wook Nam,et al.  Ionic field effect transistors with sub-10 nm multiple nanopores. , 2009, Nano letters.

[16]  Klaus Schulten,et al.  Molecular control of ionic conduction in polymer nanopores. , 2009, Faraday discussions.

[17]  Stefan Howorka,et al.  Nanopore Analytics: Sensing of Single Molecules , 2009 .

[18]  Colin Nuckolls,et al.  Translocation of Single-Stranded DNA Through Single-Walled Carbon Nanotubes , 2010, Science.

[19]  Michael S Strano,et al.  Coherence Resonance in a Single-Walled Carbon Nanotube Ion Channel , 2010, Science.

[20]  Arun Majumdar,et al.  Anomalous ion transport in 2-nm hydrophilic nanochannels. , 2010, Nature nanotechnology.

[21]  Nanofluidics: high mobility in tight spaces. , 2010, Nature nanotechnology.

[22]  Zhijun Jiang,et al.  Electrofluidic gating of a chemically reactive surface. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[23]  B. Luan,et al.  Base-by-base ratcheting of single stranded DNA through a solid-state nanopore. , 2010, Physical review letters.

[24]  B. Hinds,et al.  Highly efficient electroosmotic flow through functionalized carbon nanotube membranes. , 2011, Nanoscale.