Controllable Water Channel Gating of Nanometer Dimensions

Wan, Rundong; Li, Jinyuan; Lu, Hangjun; Fang, Haiping

doi:10.1021/ja050044d

Cited by 206 publications

(233 citation statements)

References 37 publications

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“…1. An uncapped (6,6) armchair SWCNT with a length of 1.34 nm and a diameter of 0.81 nm is embedded in two parallel graphite sheets along the z direction. The distance between the bottom end of the SWCNT and the graphite sheet is 2…”

Section: Methodsmentioning

confidence: 99%

“…An uncapped (6,6) armchair SWCNT combined with two graphite sheets is solvated in a water box of 3.5×3.5×6.3nm…”

Section: Fig 1: (Color Online)mentioning

confidence: 99%

“…Indeed, one important reason why research on nanochannel transport properties has continued to be of interest is that many primary characteristics of water confined in simple nanochannels are similar to that of complex biological channels [1][2][3][4][5][6][7] . In the past, the water transport properties have been studied extensively in singlewalled carbon nanotubes (SWCNTs) [8][9][10][11][12] .…”

Section: Introductionmentioning

confidence: 99%

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Fast water channeling across carbon nanotubes in far infrared terahertz electric fields

et al. 2016

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Using molecular dynamics simulations, we investigate systematically the water permeation properties across the single-walled carbon nanotube (SWCNT) in the presence of the terahertz electric field (TEF). With the TEF normal to the nanotube, the fracture of the hydrogen bonds results in the giant peak of net fluxes across the SWCNT with a three-fold enhancement centered around 14THz. The phenomenon is attributed to the resonant mechanisms, characterized by librational, rotational, and rotation-induced responses of in-tube polar water molecules to the TEF. For the TEF along the symmetry axis of the nanotube, the vortical modes for resonances and consequently the enhancement of net fluxes are greatly suppressed by the alignment of polar water along the symmetry axis, which characterizes the quasi one-dimensional feature of the SWCNT nicely. The resonances of water molecules in the TEF can have potential applications in the high-flux device designs used for various purposes.

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Section: Methodsmentioning

confidence: 99%

“…An uncapped (6,6) armchair SWCNT combined with two graphite sheets is solvated in a water box of 3.5×3.5×6.3nm…”

Section: Fig 1: (Color Online)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fast water channeling across carbon nanotubes in far infrared terahertz electric fields

et al. 2016

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“…Consequently a pressure gradient was induced between the two ends of a SWBNNT. Following the method proposed by Zhu et al 20 and examined by Wan et al 21 and Li et al, 22 an external force along the nanotube +z axial direction was applied to the O atoms of water molecules whose coordinates ͑in the unit cell of the periodic system͒ satisfy 0 Ͻ z Ͻ 8 Å in our simulation. The corresponding pressure is 150 MPa.…”

Section: Methodsmentioning

confidence: 99%

Transport properties and induced voltage in the structure of water-filled single-walled boron-nitrogen nanotubes

Yuan

Zhao

2009

Biomicrofluidics

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Density functional theory/molecular dynamics simulations were employed to give insights into the mechanism of voltage generation based on a water-filled singlewalled boron-nitrogen nanotube ͑SWBNNT͒. Our calculations showed that ͑1͒ the transport properties of confined water in a SWBNNT are different from those of bulk water in view of configuration, the diffusion coefficient, the dipole orientation, and the density distribution, and ͑2͒ a voltage difference of several millivolts would generate between the two ends of a SWBNNT due to interactions between the water dipole chains and charge carriers in the tube. Therefore, this structure of a water-filled SWBNNT can be a promising candidate for a synthetic nanoscale power cell as well as a practical nanopower harvesting device.

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“…Additionally, small deformations do not significantly affect flux, but any deformation beyond a critical amount will cause a reduction of flux. 13 Alternatively, mobile charges located outside the carbon nanotubes can induce an ordering of the water molecules along the nanotube channel facilitating the flow of water molecules; this can increase the magnitude of the flow by a factor 20.…”

Section: Introductionmentioning

confidence: 99%

Rapid Transport of Water via a Carbon Nanotube Syringe

Rivera

Starr

2010

J. Phys. Chem. C

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The controlled flow of water molecules at the nanoscale is an initial step to many fluidic processes in nanotechnology. Here we show how thin films of water can be drawn through a nanosyringe built from a carbon nanotube membrane and a "plunger". By increasing the speed of withdrawal of the plunger, we can obtain molecular transport through the membrane at flux rates exceeding 10 25 molecules cm -2 s -1. Above a threshold speed around 0.25 nm/ns (25 cm/s), molecules cannot fill the chamber created by the plunger motion as fast as the chamber expands, and the resulting flux rate drops. By considering hydrophobic or hydrophilic plungers, we unexpectedly find that the nature of the water-plunger interactions does not affect the flux rate or the threshold plunger speed. While the water structure near the plunger surface differs significantly for different plunger interactions, the failure of the film away from the plunger surface is responsible for loss of transport. As a result, the surface interactions play a limited role in controlling the flux.

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Controllable Water Channel Gating of Nanometer Dimensions

Cited by 206 publications

References 37 publications

Fast water channeling across carbon nanotubes in far infrared terahertz electric fields

Fast water channeling across carbon nanotubes in far infrared terahertz electric fields

Transport properties and induced voltage in the structure of water-filled single-walled boron-nitrogen nanotubes

Rapid Transport of Water via a Carbon Nanotube Syringe

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