Slip divergence of water flow in graphene nanochannels: the role of chirality

Wagemann, Enrique; Oyarzua, Elton; Walther, Jens Honoré; Zambrano, Harvey

doi:10.1039/c6cp07755b

Cited by 50 publications

(57 citation statements)

References 71 publications

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“…The reported data about slip length are widely scattered, from less than a nanometer to several micrometers. [96] For the cases of water in CNTs, the numerical simulation gives 0.81-5.42 nm of slippage [98] while experimental values are 8-53 nm, [99] depending on the channel size. Slip lengths at the scale of micrometer are not unusual, especially in experimental works.…”

Section: Flow Enhancement and Surface Slipmentioning

confidence: 94%

“…However, the slip lengths at the scale of nanometer are dominant in both numerical and experimental works. On graphene surface, the slip length for water is around 30-100 nm in molecular dynamics simulations [90,91,96] and 8 nm in experiments, [97] where the shear stress or even the chirality may make a difference. [96] For the cases of water in CNTs, the numerical simulation gives 0.81-5.42 nm of slippage [98] while experimental values are 8-53 nm, [99] depending on the channel size.…”

Section: Flow Enhancement and Surface Slipmentioning

confidence: 99%

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Structure and Transport Properties of Water and Hydrated Ions in Nano‐Confined Channels

Zhu

Wang

Fan

et al. 2019

Advcd Theory and Sims

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Nano-confined flow is ubiquitous in modern engineering and biomedical applications. As the peculiar phenomena of nano-confined flow were continuously reported and traditional theories failed to describe them accurately, simulation efforts have been made to gain deeper insight. The objective of this paper is to provide an overview of the recent progress on nano-confined flow, including water flow and hydrated ions transport. This report starts with the water behavior under nano-confinement, summarizing the water structures, flow properties and their dependence on wall wettability, channel size, etc. The report also presents the efforts made to modify the existing theories to describe nano-confined flows. Then, the report goes to the hydrated ions. The dehydration process of hydrated ions and ions sieving are discussed in detail, and the effects of membrane surface charge, grafting functional groups, and external field on ions transport are reviewed. In this Progress Report, the transport properties of water and hydrated ions in nano-confined channels are highlighted, which is critical to the design and application of nanofluidic devices, such as nanofiltration membranes, biosensors, and other related fields.

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Section: Flow Enhancement and Surface Slipmentioning

confidence: 94%

Section: Flow Enhancement and Surface Slipmentioning

confidence: 99%

Structure and Transport Properties of Water and Hydrated Ions in Nano‐Confined Channels

Zhu

Wang

Fan

et al. 2019

Advcd Theory and Sims

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“…To elucidate the effect of externally applied electric fields in capillary filling of water in hydrophilic silica nanopores, we conduct a series of all-atom MD simulations using FAST-TUBE, a molecular dynamics simulation package which has widely been used to investigate fundamental fluid dynamics under nanoconfinement. 29,42,45,[63][64][65] Water molecules are described using the simple point charge SPC/E model 66 and the silica atoms by the TTAMm model developed by Guissani and Guillot 67 which is a modification of the original TTAM model. 68 Water-silica interactions are described using Coulomb and Buckingham potentials calibrated in our previous study 69 wherein the experimental value of the water contact angle reported by Thamdrup et al 70 in studies of capillary filling is used as criterion to calibrate the potential parameters.…”

Section: Methodsmentioning

confidence: 99%

“…68 Water-silica interactions are described using Coulomb and Buckingham potentials calibrated in our previous study 69 wherein the experimental value of the water contact angle reported by Thamdrup et al 70 in studies of capillary filling is used as criterion to calibrate the potential parameters. For further details of the potentials used here, we refer readers to Zambrano et al 69 We have chosen the SPC/E water model not only to be consistent with our previous works, 42,45,63,69 but also due to its simplicity and quantitative agreement with experiments to yield water reorientation and hydrogen bond dynamics. 44,51,[71][72][73] Moreover, studies have found that the value of the surface tension for the SPC/E model is in good agreement with experimental results.…”

Section: Methodsmentioning

confidence: 99%

Effect of an external electric field on capillary filling of water in hydrophilic silica nanochannels

Karna

Rojano

Wagemann

et al. 2018

Phys. Chem. Chem. Phys.

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Development of functional nanofluidic devices requires understanding the fundamentals of capillary driven flow in nanochannels. In this context, we conduct molecular dynamics simulations of water capillary imbibition in silica nanoslits under externally applied electric (E) fields with strengths between 0 and 1 V nm-1. For increasing E-fields, we observe a systematic lowering in the meniscus contact angle and a decrease in the corresponding water filling rates. These results contrast markedly the classical Washburn-Bosanquet's equation which predicts an increase in filling rates for lower water contact angles. Our study provides evidence that the observed decrease in water filling rates can be attributed to the interplay between two underlying mechanisms, a reduced fluidity of interfacial water and a systematic alignment of the water molecules in the bulk as a response to the particular strength of the applied E-field. Therefore, during water capillary filling a constant E-field applied in the direction parallel to the water imbibition leads to a lower than expected filling rate caused by a viscosity increase in the bulk and an altered solid-liquid friction on the channel walls. These coupled mechanisms governing capillarity under the action of applied E-fields could be manipulated for controlling imbibition of polar liquid solutions in nanofluidic devices.

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“…For confined geometries the hydrodynamic equations are no longer valid, and in this case, the use of the no-slip boundary condition is at least questionable. Many experimental [1][2][3][4][5][6][7][8], theoretical, and computational [9][10][11][12][13][14][15] results report that there are several flow boundary conditions consistent with the fluid behavior and mobility [16][17][18][19] beyond the no-slip boundary condition. The amount of slip is usually measured through the magnitude of the slip length, defined as the ratio between the shear rate and the slip velocity [16][17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Relation between boundary slip mechanisms and waterlike fluid behavior

2018

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The slip of a fluid layer in contact with a solid confining surface is investigated for different temperatures and densities using molecular dynamic simulations. We show that for an anomalous waterlike fluid the slip goes as follows: for low levels of shear, defect slip appears and is related to the particle exchange between the fluid layers; at high levels of shear, global slip occurs and is related to the homogeneous distribution of the fluid in the confining surfaces. The oscillations in the transition velocity from defect to global slip are shown to be associated with changes in the layering distribution in the anomalous fluid.

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Slip divergence of water flow in graphene nanochannels: the role of chirality

Cited by 50 publications

References 71 publications

Structure and Transport Properties of Water and Hydrated Ions in Nano‐Confined Channels

Structure and Transport Properties of Water and Hydrated Ions in Nano‐Confined Channels

Effect of an external electric field on capillary filling of water in hydrophilic silica nanochannels

Relation between boundary slip mechanisms and waterlike fluid behavior

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