Bipolar nanochannels: The effects of an electro-osmotic instability. Part I: Steady-state response

TL;DR

This study investigates how electro-osmotic instability affects the steady-state current-voltage response in bipolar nanochannels, revealing differences based on internal symmetry and charge distribution.

Contribution

It provides new insights into the steady-state electrical behavior of bipolar systems, especially regarding the presence or absence of overlimiting currents based on symmetry.

Findings

Bipolar systems with internal symmetry do not show overlimiting currents.

Systems without symmetry exhibit overlimiting currents at positive voltages.

The steady-state response varies significantly with charge distribution and symmetry.

Abstract

The steady-state current-voltage response of ion-selective systems varies as the number of ion-selective components is varied. For the highly investigated unipolar system, including only one ion-selective component, it has been shown that above a supercritical voltage, an electroosmotic instability is triggered, leading to over-limiting currents. In contrast, the effects of this instability on the current-voltage response of the second most common system of a bipolar system, including two oppositely charged permselective regions, have yet to be reported. Using simulations, we investigate the steady-state electrical response of bipolar systems as we vary the ratio of the charge within the two oppositely charged regions. The responses are divided into those with an internal symmetry related to the surface charge and those without. In contrast to the unipolar systems, bipolar systems with the internal symmetry do not exhibit overlimiting currents, and their steady-state response is identical to the convectionless steady-state response. In contrast, the systems without the internal symmetry exhibit much more complicated behavior. For positive voltages, they have overlimiting currents, while for negative voltages, they do not have over-limiting currents. Our findings contribute to a more profound understanding of the behavior of the current-voltage response in bipolar systems.