Ionic Coulomb blockade as a fractional Wien effect

Kavokine, Nikita; Marbach, Sophie; Siria, Alessandro; Bocquet, Lydéric

doi:10.1038/s41565-019-0425-y

Cited by 77 publications

(100 citation statements)

References 43 publications

(74 reference statements)

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“…the study of fluidic transport at nanometer scales, has emerged as a new and interesting field in the past few decades due to novel behaviors associated to this length scale [1][2][3] e.g. dielectric anomalies of confined water 4 or intriguing ionic transport, [5][6][7] with promising applications related to new 2D materials such as the development of sustainable energies. [8][9][10] As the channel size decreases, interfacial properties have an increasingly important role.…”

Section: Introductionmentioning

confidence: 99%

Fast increase of nanofluidic slip in supercooled water: the key role of dynamics

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Fast increase of nanofluidic slip in supercooled water: the key role of dynamics

et al. 2020

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“…In many applications, solvated ions are present in nanotubes and determine most of the salient CNT properties. Consequently, ionic transport [19][20][21] and ionic conductivity 20,22,23 of CNTs are at the focus of investigations. To describe the static and kinetic ion properties inside CNTs, the continuum Poisson-Boltzmann and Helmholtz-Smoluchowski models are used [24][25][26] , but these models need as precise input predictions for the electrostatic ionion interactions, which in turn depend on the dielectric properties.…”

Section: Introductionmentioning

confidence: 99%

Giant Axial Dielectric Response in Water-Filled Nanotubes and Effective Electrostatic Ion–Ion Interactions from a Tensorial Dielectric Model

et al. 2019

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Molecular dynamics simulations in conjunction with effective medium theory are used to investigate dielectric effects in water-filled nanotubes. The resulting effective axial dielectric constant shows a divergent increase for small nanotube radii that depends on the nanotube length, while the effective radial dielectric constant decreases significantly for thin nanotubes. By solving Poisson's equation for an anisotropic dielectric medium in cylindrical geometry, we show that the axial ion-ion interaction depends for small separations primarily on the radial dielectric constant, not on the axial one. This means that electrostatic ion-ion interactions in thin water-filled nanotubes are on the linear dielectric level significantly enhanced due to water confinement effects at small separations, while at large separations the outside medium dominates. If the outside medium is metallic, the ion-ion interaction decays exponentially for large ion separation.

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“…Because of this, the electric field created by an ion within is confined to stay mostly inside the water-filled channel and does not leak into the surrounding medium. As several numerical simulations in three dimensions point out the flow field also follows almost entirely the channel direction [17][18][19]. This simple observation has profound consequences.…”

Section: Introductionmentioning

confidence: 85%

Dynamics of Ion Channels via Non-Hermitian Quantum Mechanics

Gulden

Kamenev

2021

Entropy

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We study dynamics and thermodynamics of ion transport in narrow, water-filled channels, considered as effective 1D Coulomb systems. The long range nature of the inter-ion interactions comes about due to the dielectric constants mismatch between the water and the surrounding medium, confining the electric filed to stay mostly within the water-filled channel. Statistical mechanics of such Coulomb systems is dominated by entropic effects which may be accurately accounted for by mapping onto an effective quantum mechanics. In presence of multivalent ions the corresponding quantum mechanics appears to be non-Hermitian. In this review we discuss a framework for semiclassical calculations for the effective non-Hermitian Hamiltonians. Non-Hermiticity elevates WKB action integrals from the real line to closed cycles on a complex Riemann surfaces where direct calculations are not attainable. We circumvent this issue by applying tools from algebraic topology, such as the Picard-Fuchs equation. We discuss how its solutions relate to the thermodynamics and correlation functions of multivalent solutions within narrow, water-filled channels.

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Ionic Coulomb blockade as a fractional Wien effect

Cited by 77 publications

References 43 publications

Fast increase of nanofluidic slip in supercooled water: the key role of dynamics

Fast increase of nanofluidic slip in supercooled water: the key role of dynamics

Giant Axial Dielectric Response in Water-Filled Nanotubes and Effective Electrostatic Ion–Ion Interactions from a Tensorial Dielectric Model

Dynamics of Ion Channels via Non-Hermitian Quantum Mechanics

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