Timothy S. Plett scite author profile

Rectifying nanopores feature ion currents that are higher for voltages of one polarity compared to the currents recorded for corresponding voltages of the opposite polarity. Rectification of nanopores has been found to depend on the pore opening diameter and distribution of surface charges on the pore walls as well as pore geometry. Very little is known, however, on the dependence of ionic rectification on the type of transported ions of the same charge. We performed experiments with single conically shaped nanopores in a polymer film and recorded current–voltage curves in three electrolytes: LiCl, NaCl, and KCl. Rectification degrees of the pores, quantified as the ratio of currents recorded for voltages of opposite polarities, were the highest for KCl and the lowest for LiCl. The experimental observations could not be explained by a continuum modeling based on the Poisson–Nernst–Planck equations. All-atom molecular dynamics simulations revealed differential binding between Li+, Na+, and K+ ions and carboxyl groups on the pore walls, resulting in changes to both the effective surface charge of the nanopore and cation mobility within the pore.

show abstract

Highly Charged Particles Cause a Larger Current Blockage in Micropores Compared to Neutral Particles

Qiu

Lin

Hinkle³

et al. 2016

ACS Nano

View full text Add to dashboard Cite

Single pores in the resistive-pulse technique are used as an analytics tool to detect, size, and characterize physical as well as chemical properties of individual objects such as molecules and particles. Each object passing through a pore causes a transient change of the transmembrane current called a resistive pulse. In high salt concentrations when the pore diameter is significantly larger than the screening Debye length, it is assumed that the particle size and surface charge can be determined independently from the same experiment. In this article we challenge this assumption and show that highly charged hard spheres can cause a significant increase of the resistive-pulse amplitude compared to neutral particles of a similar diameter. As a result, resistive pulses overestimate the size of charged particles by even 20%. The observation is explained by the effect of concentration polarization created across particles in a pore, revealed by numerical modeling of ionic concentrations, ion current, and local electric fields. It is notable that in resistive-pulse experiments with cylindrical pores, concentration polarization was previously shown to influence ionic concentrations only at pore entrances; consequently, additional and transient modulation of resistive pulses was observed when a particle entered or left the pore. Here we postulate that concentration polarization can occur across transported particles at any particle position along the pore axis and affect the magnitude of the entire resistive pulse. Consequently, the recorded resistive pulses of highly charged particles reflect not only the particles' volume but also the size of the depletion zone created in front of the moving particle. Moreover, the modeling identified that the effective surface charge density of particles depended not only on the density of functional groups on the particle but also on the capacitance of the Stern layer. The findings are of crucial importance for sizing particles and characterizing their surface charge properties.

show abstract

Rectification of nanopores in aprotic solvents – transport properties of nanopores with surface dipoles

et al. 2015

View full text Add to dashboard Cite

Nanopores have become a model system to understand transport properties at the nanoscale. We report experiments and modeling of ionic current in aprotic solvents with different dipole moments through conically shaped nanopores in a polycarbonate film and through glass nanopipettes. We focus on solutions of the salt LiClO4, which is of great importance in modeling lithium based batteries. Results presented suggest ion current rectification observed results from two effects: (i) adsorption of Li(+) ions to the pore walls, and (ii) a finite dipole moment rendered by adsorbed solvent molecules. Properties of surfaces in various solvents were probed by means of scanning ion conductance microscopy, which confirmed existence of an effectively positive surface potential in aprotic solvents with high dipole moments.

show abstract

Solid-State Ionic Diodes Demonstrated in Conical Nanopores

et al. 2017

View full text Add to dashboard Cite

Ionic transport at the nanoscale features phenomena that are not observed in larger systems. Nonlinear current− voltage curves characteristic of ionic diodes as well as ion selectivity are examples of effects observed at the nanoscale. Many manmade nanopore systems are inspired by biological channels in a cell membrane, thus measurements are often performed in aqueous solutions. Consequently, much less is known about ionic transport in nonaqueous systems, especially in solid-state electrolytes. Here we show ionic transport through single pores filled with gel electrolyte of poly(methyl methacrylate) (PMMA) doped with LiClO 4 in propylene carbonate. The system has no liquid interface and the ionic transport occurs through the porous gel structure. We demonstrate that a conically shaped nanopore filled with the gel rectifies the current and works as a solid-state ionic diode.

show abstract

Ion transport in gel and gel–liquid systems for LiClO₄-doped PMMA at the meso- and nanoscales

et al. 2017

View full text Add to dashboard Cite

Solid and gel electrolytes offer significant advantages for cycle stability and longevity in energy storage technologies. These advantages come with trade-offs such as reduced conductivity and ion mobility, which can impact power density in storage devices even at the nanoscale. Here we propose experiments aimed at exploring the ion transport properties of a hybrid electrolyte system of liquid and gel electrolytes with meso and nanoscale components. We focus on single pore systems featuring LiClO-propylene carbonate and LiClO-PMMA gel, which are model electrolytes for energy storage devices. We identified conditions at which the systems considered featured rectifying current-voltage curves, indicating a preferential direction of ion transport. The presented ion current rectification suggests different mechanisms arising from the unique hybrid system: (i) PMMA structure imposing selectivity in fully immersed systems and (ii) ionic selectivity linked to ion sourcing from media of different ionic mobility. These mechanisms were observed to interplay with ion transport properties linked to nanopore structure i.e. cylindrical and conical.

show abstract

Ionic conductivity of a single porous MnO₂mesorod at controlled oxidation states

et al. 2015

View full text Add to dashboard Cite

show abstract

Dipole Effects on Ion Transport Demonstrated in Aprotic Solvents

Plett

Shi

Zeng

et al. 2016

Biophysical Journal

View full text Add to dashboard Cite

changes in nucleosomes. Our immediate goal is to measure the structural changes in single nucleosomes and nucleosome arrays in response to transcription factor (TF) binding. Initial experiments using the nucleosomecaliper construct with GAL4-VP16, a hybrid transcription factor capable of highly-efficient transcription activation, shows that the angular distribution broadens as a result of increasing TF concentrations. Our measurements revealed a dissociation constant in the range of 1-10nM, which agrees with bulk measurements. These results demonstrate the potential of a DNA origami device probing chromatin structure and function in vitro, in particular, the ability to measure structural changes in the range of 10-100nm.

show abstract

Ion Transport Through Synthetic Nanopores Deposited in Porous Manganese Oxide Wires

Plett

Gamble

Gillette

et al. 2015

Biophysical Journal

View full text Add to dashboard Cite

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

hi@scite.ai

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Timothy S. Plett

Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling

Highly Charged Particles Cause a Larger Current Blockage in Micropores Compared to Neutral Particles

Rectification of nanopores in aprotic solvents – transport properties of nanopores with surface dipoles

Solid-State Ionic Diodes Demonstrated in Conical Nanopores

Ion transport in gel and gel–liquid systems for LiClO₄-doped PMMA at the meso- and nanoscales

Ionic conductivity of a single porous MnO₂mesorod at controlled oxidation states

Dipole Effects on Ion Transport Demonstrated in Aprotic Solvents

Ion Transport Through Synthetic Nanopores Deposited in Porous Manganese Oxide Wires

Contact Info

Product

Resources

About

Timothy S. Plett

Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling

Highly Charged Particles Cause a Larger Current Blockage in Micropores Compared to Neutral Particles

Rectification of nanopores in aprotic solvents – transport properties of nanopores with surface dipoles

Solid-State Ionic Diodes Demonstrated in Conical Nanopores

Ion transport in gel and gel–liquid systems for LiClO4-doped PMMA at the meso- and nanoscales

Ionic conductivity of a single porous MnO2mesorod at controlled oxidation states

Dipole Effects on Ion Transport Demonstrated in Aprotic Solvents

Ion Transport Through Synthetic Nanopores Deposited in Porous Manganese Oxide Wires

Contact Info

Product

Resources

About

Ion transport in gel and gel–liquid systems for LiClO₄-doped PMMA at the meso- and nanoscales

Ionic conductivity of a single porous MnO₂mesorod at controlled oxidation states