The role of fluid-wall interactions on confined liquid diffusion using Mori theory

Devi, Reena; Srivastava, Sunita; Tankeshwar, K.

doi:10.1063/1.4926619

Cited by 8 publications

(7 citation statements)

References 45 publications

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“…2(b), the amplitude of the density oscillations rapidly decays while approaching the bulk volume of the fluid. 18,23,51,58 It is noteworthy that the values of the density at the near-constant plateaus in the center of the channel are slightly, but noticeably, different for the hydrophilic and hydrophobic cases. This is a manifestation of the Kelvin shift of the bulk coexistence curve, which occurs due to the spatial confinement of the fluid, 59 reflecting the higher degree of effective confinement in the hydrophobic case due to the repulsive wall layer.…”

Section: A Equilibrium Density Profilesmentioning

confidence: 99%

Nonequilibrium molecular dynamics simulations of nanoconfined fluids at solid-liquid interfaces

Morciano

Fasano

Nold

et al. 2017

The Journal of Chemical Physics

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We investigate the hydrodynamic properties of a Lennard-Jones fluid confined to a nanochannel using molecular dynamics simulations. For channels of different widths and hydrophilic-hydrophobic surface wetting properties, profiles of the fluid density, stress, and viscosity across the channel are obtained and analysed. In particular, we propose a linear relationship between the density and viscosity in confined and strongly inhomogeneous nanofluidic flows. The range of validity of this relationship is explored in the context of coarse grained models such as dynamic density functional-theory.

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Section: A Equilibrium Density Profilesmentioning

confidence: 99%

Nonequilibrium molecular dynamics simulations of nanoconfined fluids at solid-liquid interfaces

Morciano

Fasano

Nold

et al. 2017

The Journal of Chemical Physics

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“…Less is known on thermodynamic and transport properties of the fluid in the adsorbed layers [15]. MD simulations have been used before to study the following properties of simple fluids adsorbed to walls: self-diffusivity [8,[15][16][17][18][19][20][21][22][23][24], thermal conductivity [23,[25][26][27][28][29], and shear viscosity [23,29,30]. In most of these studies, fluid properties were determined as mean values in nanochannels that were so small that the adsorbed layers on both walls interfered [1,5,6,13,16,31,32].…”

Section: Introductionmentioning

confidence: 99%

Thermal, caloric and transport properties of the Lennard–Jones truncated and shifted fluid in the adsorbed layers at dispersive solid walls

Lautenschlaeger

Hasse

2019

Molecular Physics

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Fluid properties change when the fluid is adsorbed at a wall. The effect of the adsorption on the fluid properties was studied here by molecular simulation. There is much previous work in this field on fluids in nanochannels that are so small that the adsorbed layers on both walls interfere. In the present work the channel width was so large that the adsorbed layers did not interfere, such that information on the adsorbed layer on single walls was obtained and average values of thermodynamic properties of the fluid in that layer were determined.The studied fluid properties are: pressure p, density ρ, internal energy u, enthalpy h, isobaric heat capacity c p , thermal expansion coefficient α p , thermal conductivity λ, shear viscosity η, and self-diffusion coefficient D. For the study, non-equilibrium molecular dynamics simulations were carried out, i.e. gradients of the temperature and the velocity along different directions were applied. The fluid and the solid were modeled with the Lennard-Jones potential truncated and shifted at r * c = 2.5 σ. The overall density of the fluid was always ρ = 0.8 in the present simulations. The overall temperature as well as the solid-fluid interaction were varied. The corresponding bulk states are liquid or supercritical. The results for the fluid properties in the adsorbed layer were compared to the corresponding bulk values and the deviations were found to be generally below 15 %.

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“…The varied atomic co-ordination manifesting as under- or over-coordination of atoms in a GB creates dangling bonds that can facilitate formation of native defects and segregation of dopants. 8 As GBs with different angles affects the material properties in different ways, 30 ZnO GBs with low and high angles 31 characterized by short and long periodicity were investigated previously. For example, Sato et al 32 obtained a wide variety of GB atomic structures in ZnO solely by changing the relative orientation of the GB planes.…”

Section: Resultsmentioning

confidence: 99%

“…Both stoichiometric and non-stoichiometric GBs have been found to significantly affect the properties of ZnO materials, such as producing distinct occupied and unoccupied levels, with changes in the coordination and concentration of O atoms, which in turn produces varistor effect in the undoped conditions. 9 Recently, we have also demonstrated FM in ZnO GB in presence of cation vacancies, 8 wherein FM originates from the localized holes forming triplet states, thus giving rise to a stable magnetic ground state. 10 This magnetic phenomenon originates from the p band, rather than the d band (in which case it is referred to as the d 0 FM.…”

Section: Introductionmentioning

confidence: 99%

“… 1 While GaAs and GaN based DMS were the subject of most prior investigations in this field, 2 the focus has recently shifted to ZnO, as it exhibits room temperature ferromagnetism (RTFM) in presence of transition metals (TMs) 3 and rare earth (RE) elements. 4–7,19 The existence of intrinsic defects, such as dislocations, grain boundaries (GBs), and vacancies in ZnO also assists in inducing magnetic properties, 8 and the ferromagnetic coupling strength is increased when defect-dopant complexes are present in the material. 3 In particular, ZnO GB can play a role in the ferromagnetism (FM) of ZnO.…”

Section: Introductionmentioning

confidence: 99%

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Analysis on the energetics, magnetism and electronic properties in a 45° ZnO grain boundary doped with Gd

Aravindh

Roqan

2018

RSC Adv.

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The structural stability and magnetic properties of a grain boundary (GB) formed by aligning two ZnO single crystals oriented at an angle of 45 is investigated by density functional theory, using generalized gradient approximation (GGA) and taking the U parameter into consideration for the 4f impurity states. We found that the GB is stable with no dangling bonds and inter-granular structures. The stability of defects such as Gd substituted to the Zn site (Gd Zn ), Zn vacancy (V Zn ) and O vacancy (V O ) as well as defect complexes Gd Zn -Gd Zn , Gd Zn -V Zn , and Gd Zn -V O are analyzed using formation energy calculations. It is found that Gd Zn -Gd Zn clusters prefers to form at the GB. The spin polarization at the Gd Zn sites is too localized and the exchange coupling energy is insufficient to overcome the thermal fluctuations. However, we show that the presence of V Zn increases the hybridization between p orbitals of O as well as d orbitals of Zn, which can assist in increasing the magnetic polarization of the system. This work advances the understanding of the ferromagnetism in Gd-doped ZnO, indicating that Gd clustering at the GB is not likely to contribute to the ferromagnetism.

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The role of fluid-wall interactions on confined liquid diffusion using Mori theory

Cited by 8 publications

References 45 publications

Nonequilibrium molecular dynamics simulations of nanoconfined fluids at solid-liquid interfaces

Nonequilibrium molecular dynamics simulations of nanoconfined fluids at solid-liquid interfaces

Thermal, caloric and transport properties of the Lennard–Jones truncated and shifted fluid in the adsorbed layers at dispersive solid walls

Analysis on the energetics, magnetism and electronic properties in a 45° ZnO grain boundary doped with Gd

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