Effects of nanoscale density inhomogeneities on shearing fluids

Dalton, Ben; Daivis, Peter J.; Hansen, Jesper Schmidt; Todd, B. D.

doi:10.1103/physreve.88.052143

Cited by 11 publications

(23 citation statements)

References 36 publications

(96 reference statements)

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“…We know that thermal expansion and normal pressure differences due to shear may induce density inhomogeneities [7,12]. The shear-induced density inhomogeneity is due to the even-order contributions of F x (y).…”

Section: A Density Responsementioning

confidence: 99%

“…In Ref. [7] we saw that for large values of the STF strengths, higher-order nonlinear terms are induced in the velocity profile of shearing fluids. This effect is independent of the SLF strength.…”

Section: B Strain Rate and Shear Pressure Responsementioning

confidence: 99%

“…The LADM introduces a viscosity that depends nonlocally on the density but is independent of the strain rate, which is then used to define a constitutive equation for the shear pressure that depends locally on the strain rate. The LADM represents a considerable improvement over the fully local model, but it still fails to describe some features of the velocity profiles that have been observed in molecular-dynamics simulations of confined fluid flow [6,7]. Hoang and Galliero [8,9] have recently investigated the effect of density inhomogeneity on shear flow by combining simple planar shear with a sinusoidally varying potential (SVP) to create density inhomogeneities.…”

Section: Introductionmentioning

confidence: 99%

“…In a recent paper, we extended this method by combining the SLF with a sinusoidal transverse force (STF) to generate shear flow in an inhomogeneous fluid [7]. The STF method is well known as a method for studying the wave-vector-dependent viscosity, which is the Fourier transform of the spatial viscosity kernel [3,10,11].…”

Section: Introductionmentioning

confidence: 99%

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Nonlocal response functions for predicting shear flow of strongly inhomogeneous fluids. I. Sinusoidally driven shear and sinusoidally driven inhomogeneity

et al. 2015

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We present theoretical expressions for the density, strain rate, and shear pressure profiles in strongly inhomogeneous fluids undergoing steady shear flow with periodic boundary conditions. The expressions that we obtain take the form of truncated functional expansions. In these functional expansions, the independent variables are the spatially sinusoidal longitudinal and transverse forces that we apply in nonequilibrium molecular-dynamics simulations. The longitudinal force produces strong density inhomogeneity, and the transverse force produces sinusoidal shear. The functional expansions define new material properties, the response functions, which characterize the system's nonlocal response to the longitudinal force and the transverse force. We find that the sinusoidal longitudinal force, which is mainly responsible for the generation of density inhomogeneity, also modulates the strain rate and shear pressure profiles. Likewise, we find that the sinusoidal transverse force, which is mainly responsible for the generation of sinusoidal shear flow, can also modify the density. These cross couplings between density inhomogeneity and shear flow are also characterized by nonlocal response functions. We conduct nonequilibrium molecular-dynamics simulations to calculate all of the response functions needed to describe the response of the system for weak shear flow in the presence of strong density inhomogeneity up to the third order in the functional expansion. The response functions are then substituted directly into the truncated functional expansions and used to predict the density, velocity, and shear pressure profiles. The results are compared to the directly evaluated profiles from molecular-dynamics simulations, and we find that the predicted profiles from the truncated functional expansions are in excellent agreement with the directly computed density, velocity, and shear pressure profiles.

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Section: A Density Responsementioning

confidence: 99%

Section: B Strain Rate and Shear Pressure Responsementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Nonlocal response functions for predicting shear flow of strongly inhomogeneous fluids. I. Sinusoidally driven shear and sinusoidally driven inhomogeneity

et al. 2015

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“…For mass control, there are a number of particle insertion techniques such as USHER 10 and FADE 11 as well as mass control by the pycnostat. 12 Control of intermolecular separation is possible using iterative schemes which enforce constraints with algorithms such as SHAKE and its derivatives. 13 Synthetic equations of motion have been proposed to impose flow profiles which act on the entire simulation domain (i.e., the whole periodic cell 8 ).…”

Section: Introductionmentioning

confidence: 99%

A localized momentum constraint for non-equilibrium molecular dynamics simulations

Smith

Heyes

Dini

et al. 2015

The Journal of Chemical Physics

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Articles you may be interested inEfficient hybrid non-equilibrium molecular dynamics -Monte Carlo simulations with symmetric momentum reversal J. Chem. Phys. 141, 114107 (2014) A term for the advection of molecules appears in the derived constraint and is shown to be essential in order to exactly control the time evolution of momentum in the subvolume. The numerical procedure converges the total momentum in the CV to the target value to within machine precision in an iterative manner. The localized momentum constraint can prescribe essentially arbitrary flow fields in non-equilibrium molecular dynamics simulations. The methodology also forms a rigorous mathematical framework for introducing coupling constraints at the boundary between continuum and discrete systems. This functionality is demonstrated with a boundary-driven flow test case. C 2015 AIP Publishing LLC.[http://dx

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Continuum Nanofluidics

et al. 2015

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This paper introduces the fundamental continuum theory governing momentum transport in isotropic nanofluidic flows. The theory is an extension to the classical Navier-Stokes equation, which includes coupling between translational and rotational degrees of freedom, as well as nonlocal response functions that incorporates spatial correlations. The continuum theory is compared with molecular dynamics simulation data for both relaxation processes and fluid flows showing excellent agreement on the nanometer length scale. We also present practical tools to estimate when the extended theory should be used. It is shown that in the wall-fluid region the fluid molecules align with the wall and in this region the isotropic model may fail and a full anisotropic description is necessary in order to describe this region. * jschmidt@ruc.dk 2

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Effects of nanoscale density inhomogeneities on shearing fluids

Cited by 11 publications

References 36 publications

Nonlocal response functions for predicting shear flow of strongly inhomogeneous fluids. I. Sinusoidally driven shear and sinusoidally driven inhomogeneity

Nonlocal response functions for predicting shear flow of strongly inhomogeneous fluids. I. Sinusoidally driven shear and sinusoidally driven inhomogeneity

A localized momentum constraint for non-equilibrium molecular dynamics simulations

Continuum Nanofluidics

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