Graphite nanoslits with selective inlet charging exhibit bipolar pressure-dependent ionic conductance via advection of excess ions by pressure-driven flow, as captured by an electrohydrodynamic model.
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2 Pith papers cite this work. Polarity classification is still indexing.
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2026 2verdicts
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A formalized Poisson-Boltzmann framework classifies EDL regimes in confined spaces and predicts 60 mV/dec and 120 mV/dec thermodynamic limits for electrostatic control of nanofluidic ion transport.
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Architecting mechanosensitive nanofluidic transport in graphite nanoslits
Graphite nanoslits with selective inlet charging exhibit bipolar pressure-dependent ionic conductance via advection of excess ions by pressure-driven flow, as captured by an electrohydrodynamic model.
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Formalizing Poisson-Boltzmann Theory for Field-Tunable Nanofluidic Devices
A formalized Poisson-Boltzmann framework classifies EDL regimes in confined spaces and predicts 60 mV/dec and 120 mV/dec thermodynamic limits for electrostatic control of nanofluidic ion transport.