Journal
ACS NANO
Volume 7, Issue 12, Pages 11272-11282Publisher
AMER CHEMICAL SOC
DOI: 10.1021/nn4050485
Keywords
nanopipette; ion current rectification; finite-element simulation; charged interface; Poisson-Nernst-Planck equations
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Funding
- National Institutes of Health [NIDDK 1R21DK082990]
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We describe ion distribution and the current voltage (i-V) response of nanopipettes at different probe-to-substrate distances (D-ps) as simulated by finite-element methods. Results suggest electrostatic interactions between a charged substrate and the nanopipette dominate electrophoretic ion transport through the nanopipette when D-ps is within 1 order of magnitude of the Debye length (similar to 10 nm for a 1 mM solution as employed in the simulation). Ion current rectification (ICR) and permselectivity associated with a neutral or charged nanopipette can be reversibly enhanced or reduced dependent on D-ps, charge polarity, and charge density (sigma) of the substrate. Regulation of nanopipette current is a consequence of the enrichment or depletion of ions within the nanopipette interior, which influences conductivity of the nanopipette. When the external substrate is less negatively charged than the nanopipette, the substrate first reduces, and then enhances the ICR as D-ps decreases. Surprisingly, both experimental and simulated data show that a neutral substrate was also able to reduce and reverse the ICR of a slightly negatively charged nanopipette. Simulated results ascribe such effects to the elimination of ion depletion within the nanopipette at positive potentials.
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