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Main Authors: Sharvit, Ayelet Ben-Kish, Green, Yoav
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.14080
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author Sharvit, Ayelet Ben-Kish
Green, Yoav
author_facet Sharvit, Ayelet Ben-Kish
Green, Yoav
contents Bipolar nanoporous membranes and bipolar nanochannels are used in water desalination and energy-harvesting systems that provide clean water and green energy, respectively. The growing need for both requires continuous improvement of their performance. However, the underlying physics of these complex systems is still not fully understood, making empirical optimization slow and inefficient. In this work, we combine theoretical analysis and numerical simulations to develop a unified framework for improving the design of nanofluidic devices. We show that the system response is governed by the interplay between the applied voltage and a parameter $η$, which depends on the ratio of geometry and surface charge densities of both charged regions. At low voltages, the response is mostly determined by $η$, allowing its dependence to be represented by a simplified phase space. At high voltages, this phase space becomes oversimplified. To demonstrate the framework's robustness, we scan a range of configurations, from unipolar channels (single charged region) to bipolar channels (positive and negative segments). We compare the numerically simulated current-voltage responses with three theoretical models, which are limiting scenarios within the phase space, and explain the observed deviations. These findings can help reduce the time and resources required to optimize nanofluidic devices and improve the interpretation of experiments and simulations.
format Preprint
id arxiv_https___arxiv_org_abs_2510_14080
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Towards a unified mechanistic understanding of the electrical response of bipolar nanofluidic systems
Sharvit, Ayelet Ben-Kish
Green, Yoav
Mesoscale and Nanoscale Physics
35Q92, 76M25, 82D80
Bipolar nanoporous membranes and bipolar nanochannels are used in water desalination and energy-harvesting systems that provide clean water and green energy, respectively. The growing need for both requires continuous improvement of their performance. However, the underlying physics of these complex systems is still not fully understood, making empirical optimization slow and inefficient. In this work, we combine theoretical analysis and numerical simulations to develop a unified framework for improving the design of nanofluidic devices. We show that the system response is governed by the interplay between the applied voltage and a parameter $η$, which depends on the ratio of geometry and surface charge densities of both charged regions. At low voltages, the response is mostly determined by $η$, allowing its dependence to be represented by a simplified phase space. At high voltages, this phase space becomes oversimplified. To demonstrate the framework's robustness, we scan a range of configurations, from unipolar channels (single charged region) to bipolar channels (positive and negative segments). We compare the numerically simulated current-voltage responses with three theoretical models, which are limiting scenarios within the phase space, and explain the observed deviations. These findings can help reduce the time and resources required to optimize nanofluidic devices and improve the interpretation of experiments and simulations.
title Towards a unified mechanistic understanding of the electrical response of bipolar nanofluidic systems
topic Mesoscale and Nanoscale Physics
35Q92, 76M25, 82D80
url https://arxiv.org/abs/2510.14080