Rectification properties of conically shaped nanopores: consequences of miniaturization

Nanopores attracted a great deal of scientific interest as templates for biological sensors as well as model systems to understand transport phenomena at the nanoscale. The experimental and theoretical analysis of nanopores has been so far focused on understanding the effect of the pore opening diam...

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Veröffentlicht in:	Physical chemistry chemical physics : PCCP 2013-10, Vol.15 (39), p.16917-16926
Hauptverfasser:	Pietschmann, J.-F, Wolfram, M.-T, Burger, M, Trautmann, C, Nguyen, G, Pevarnik, M, Bayer, V, Siwy, Z
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Sprache:	eng
Schlagworte:	Chemistry Colloidal state and disperse state Computer simulation Exact sciences and technology General and physical chemistry Ion currents Mathematical analysis Mathematical models Nanostructure Porosity Porous materials Rectification Reservoirs
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creator	Pietschmann, J.-F Wolfram, M.-T Burger, M Trautmann, C Nguyen, G Pevarnik, M Bayer, V Siwy, Z
description	Nanopores attracted a great deal of scientific interest as templates for biological sensors as well as model systems to understand transport phenomena at the nanoscale. The experimental and theoretical analysis of nanopores has been so far focused on understanding the effect of the pore opening diameter on ionic transport. In this article we present systematic studies on the dependence of ion transport properties on the pore length. Particular attention was given to the effect of ion current rectification exhibited in conically shaped nanopores with homogeneous surface charges. We found that reducing the length of conically shaped nanopores significantly lowered their ability to rectify ion current. However, rectification properties of short pores can be enhanced by tailoring the surface charge and the shape of the narrow opening. Furthermore we analyzed the relationship of the rectification behavior and ion selectivity for different pore lengths. All simulations were performed using MsSimPore, a software package for solving the Poisson-Nernst-Planck (PNP) equations. It is based on a novel finite element solver and allows for simulations up to surface charge densities of −2 e per nm 2 . MsSimPore is based on 1D reduction of the PNP model, but allows for a direct treatment of the pore with bulk electrolyte reservoirs, a feature which was previously used in higher dimensional models only. MsSimPore includes these reservoirs in the calculations, a property especially important for short pores, where the ionic concentrations and the electric potential vary strongly inside the pore as well as in the regions next to the pore entrance. Systematic studies on the dependence of ion transport properties on the pore length are performed with particular attention to the effect of ion current rectification exhibited in conically shaped nanopores with homogeneous surface charges.
doi_str_mv	10.1039/c3cp53105h
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The experimental and theoretical analysis of nanopores has been so far focused on understanding the effect of the pore opening diameter on ionic transport. In this article we present systematic studies on the dependence of ion transport properties on the pore length. Particular attention was given to the effect of ion current rectification exhibited in conically shaped nanopores with homogeneous surface charges. We found that reducing the length of conically shaped nanopores significantly lowered their ability to rectify ion current. However, rectification properties of short pores can be enhanced by tailoring the surface charge and the shape of the narrow opening. Furthermore we analyzed the relationship of the rectification behavior and ion selectivity for different pore lengths. All simulations were performed using MsSimPore, a software package for solving the Poisson-Nernst-Planck (PNP) equations. It is based on a novel finite element solver and allows for simulations up to surface charge densities of −2 e per nm 2 . MsSimPore is based on 1D reduction of the PNP model, but allows for a direct treatment of the pore with bulk electrolyte reservoirs, a feature which was previously used in higher dimensional models only. MsSimPore includes these reservoirs in the calculations, a property especially important for short pores, where the ionic concentrations and the electric potential vary strongly inside the pore as well as in the regions next to the pore entrance. 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It is based on a novel finite element solver and allows for simulations up to surface charge densities of −2 e per nm 2 . MsSimPore is based on 1D reduction of the PNP model, but allows for a direct treatment of the pore with bulk electrolyte reservoirs, a feature which was previously used in higher dimensional models only. MsSimPore includes these reservoirs in the calculations, a property especially important for short pores, where the ionic concentrations and the electric potential vary strongly inside the pore as well as in the regions next to the pore entrance. 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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Chemistry Colloidal state and disperse state Computer simulation Exact sciences and technology General and physical chemistry Ion currents Mathematical analysis Mathematical models Nanostructure Porosity Porous materials Rectification Reservoirs
title	Rectification properties of conically shaped nanopores: consequences of miniaturization
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