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

Zhu, Huajian; Wang, Yuying; Fan, Yiqun; Xu, Jun; Yang, Chao

doi:10.1002/adts.201900016

Cited by 53 publications

(50 citation statements)

References 186 publications

(502 reference statements)

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“…These effects have also been discussed in detail in the context of CNTs and related pores by Wu et al 203 (see section 5.1 ) and in a recent review. 204 …”

Section: Simplified Models Of Nanoporesmentioning

confidence: 99%

“…Nonbiological nanopores, especially carbon nanotubes (CNTs), are an active area of research on the behavior of nanoconfined water in pores ( Figure 8 ). A recent review, 204 mainly focused on CNTs, compares MD and continuum approaches to water flow in such nanopores. In this section we will first discuss more recent simulation studies of water in CNTs, before examining a range of other nonbiological nanopores.…”

Section: Nonbiological Nanoporesmentioning

confidence: 99%

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Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

2020

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This Review explores the dynamic behavior of water within nanopores and biological channels in lipid bilayer membranes. We focus on molecular simulation studies, alongside selected structural and other experimental investigations. Structures of biological nanopores and channels are reviewed, emphasizing those high-resolution crystal structures, which reveal water molecules within the transmembrane pores, which can be used to aid the interpretation of simulation studies. Different levels of molecular simulations of water within nanopores are described, with a focus on molecular dynamics (MD). In particular, models of water for MD simulations are discussed in detail to provide an evaluation of their use in simulations of water in nanopores. Simulation studies of the behavior of water in idealized models of nanopores have revealed aspects of the organization and dynamics of nanoconfined water, including wetting/dewetting in narrow hydrophobic nanopores. A survey of simulation studies in a range of nonbiological nanopores is presented, including carbon nanotubes, synthetic nanopores, model peptide nanopores, track-etched nanopores in polymer membranes, and hydroxylated and functionalized nanoporous silica. These reveal a complex relationship between pore size/geometry, the nature of the pore lining, and rates of water transport. Wider nanopores with hydrophobic linings favor water flow whereas narrower hydrophobic pores may show dewetting. Simulation studies over the past decade of the behavior of water in a range of biological nanopores are described, including porins and β-barrel protein nanopores, aquaporins and related polar solute pores, and a number of different classes of ion channels. Water is shown to play a key role in proton transport in biological channels and in hydrophobic gating of ion channels. An overall picture emerges, whereby the behavior of water in a nanopore may be predicted as a function of its hydrophobicity and radius. This informs our understanding of the functions of diverse channel structures and will aid the design of novel nanopores. Thus, our current level of understanding allows for the design of a nanopore which promotes wetting over dewetting or vice versa. However, to design a novel nanopore, which enables fast, selective, and gated flow of water de novo would remain challenging, suggesting a need for further detailed simulations alongside experimental evaluation of more complex nanopore systems.

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“…These effects have also been discussed in detail in the context of CNTs and related pores by Wu et al 203 (see section 5.1 ) and in a recent review. 204 …”

Section: Simplified Models Of Nanoporesmentioning

confidence: 99%

Section: Nonbiological Nanoporesmentioning

confidence: 99%

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

2020

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“…Several simulations have indeed predicted enhanced self‐diffusivities for large ions inside CNT channels, and a few self‐diffusion experiments seem to support these claims. [ 20–26 ] In addition, our previous reports have shown water vapor permeances under a relative humidity gradient that are 24–100 times larger than Knudsen theory estimates, [ 14,27 ] and others have measured proton diffusivity in very narrow CNTs exceeding bulk transport by ten times. [ 28 ] Unfortunately, conclusive experimental validation of enhanced diffusion in liquid phases has remained elusive thus far.…”

Section: Figurementioning

confidence: 99%

Fast Permeation of Small Ions in Carbon Nanotubes

et al. 2020

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Simulations and experiments have revealed enormous transport rates through carbon nanotube (CNT) channels when a pressure gradient drives fluid flow, but comparatively little attention has been given to concentration‐driven transport despite its importance in many fields. Here, membranes are fabricated with a known number of single‐walled CNTs as fluid transport pathways to precisely quantify the diffusive flow through CNTs. Contrary to early experimental studies that assumed bulk or hindered diffusion, measurements in this work indicate that the permeability of small ions through single‐walled CNT channels is more than an order of magnitude higher than through the bulk. This flow enhancement scales with the ion free energy of transfer from bulk solutions to a nanoconfined, lower‐dielectric environment. Reported results suggest that CNT membranes can unlock dialysis processes with unprecedented efficiency.

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“…The hydration of ions and the transport dynamics are widely studied in areas such as desalination and biological channels 19 . Figure 1 depicts the hydration structure of a cation.…”

Section: Hydration Of Cationsmentioning

confidence: 99%

“…Certain number of water molecules are closely coordinated with the cation through bonding with oxygen, forming an inner hydration sphere. Conventionally, the hydration number was determined by means of atomic force microscopy, 20 X‐ray absorption spectroscopy (XAS), 21 infrared photodissociation spectroscopy, 22 Raman spectroscopy, 23 luminescence, 24 nuclear magnetic resonance, 25 neutron scattering, 26 and so forth in combination with molecular dynamics simulation 19 . Free water molecules farther away from the inner hydration shell are loosely bonded through hydrogen bond and form an outer hydration sphere.…”

Section: Hydration Of Cationsmentioning

confidence: 99%

Intercalated water in aqueous batteries

Xiao

2020

Carbon Energy

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The unprecedentedly growing demand for energy storage devices in recent years calls for diversified chemistries with unique advantages. When it comes to safety and cost, aqueous battery systems have attracted tremendous attention. Owing to its small size, high polarity, and hydrogen bonding, water in the electrode materials, either in the form of structural water or cointercalated hydrated cations, drastically change the electrochemical behavior through multiple aspects. This review discusses the roles of water in aqueous batteries from how water molecules coordinate with cations to examples of water‐mediated reactions in different types of host materials.

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

Cited by 53 publications

References 186 publications

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

Fast Permeation of Small Ions in Carbon Nanotubes

Intercalated water in aqueous batteries

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