Lattice Boltzmann simulations of pressure-driven flows in microchannels using Navier–Maxwell slip boundary conditions

Reis, Timothy; Dellar, Paul J.

doi:10.1063/1.4764514

Cited by 45 publications

(28 citation statements)

References 55 publications

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“…In other words, one cannot accurately capture the Knudsen layer without resolving the endpoint singularities [32]. Thus one cannot hope to capture the Knudsen layer or its manifestation a priori by using the lattice Boltzmann equation [50][51][52][53] or similar schemes, which is a special case of the linearized BGKW equation in the diffusive limit [54] and is incapable to capture any Knudsen-number effects beyond the Navier-Stokes equations [55][56][57].…”

Section: Discussionmentioning

confidence: 96%

Analysis and accurate numerical solutions of the integral equation derived from the linearized BGKW equation for the steady Couette flow

Jiang

Luo

2016

Journal of Computational Physics

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The integral equation for the flow velocity u(x; k) in the steady Couette flow derived from the linearized Bhatnagar-Gross-Krook-Welander kinetic equation is studied in detail both theoretically and numerically in a wide range of the Knudsen number k between 0.003 and 100.0. First, it is shown that the integral equation is a Fredholm equation of the second kind in which the norm of the compact integral operator is less than 1 on L p for any 1 ≤ p ≤ ∞ and thus there exists a unique solution to the integral equation via the Neumann series. Second, it is shown that the solution is logarithmically singular at the endpoints.More precisely, if x = 0 is an endpoint, then the solution can be expanded as a double power series of the form ∞ n=0 ∞ m=0 c n,m x n (x ln x) m about x = 0 on a small interval x ∈ (0, a) for some a > 0. And third, a high-order adaptive numerical algorithm is designed to compute the solution numerically to high precision. The solutions for the flow velocity u(x; k), the stress P xy (k), and the half-channel mass flow rate Q (k) are obtained in a wide range of the Knudsen number 0.003 ≤ k ≤ 100.0; and these solutions are accurate for at least twelve significant digits or better, thus they can be used as benchmark solutions.

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Section: Discussionmentioning

confidence: 96%

Analysis and accurate numerical solutions of the integral equation derived from the linearized BGKW equation for the steady Couette flow

Jiang

Luo

2016

Journal of Computational Physics

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“…The first two conditions (9.4a) and (9.4b) impose no-flux and no-slip boundary conditions, and the third boundary condition (9.4c) on the tangential stress has a natural physical interpretation, unlike the alternatives involving higher moments [5,6,75] …”

Section: Implementation Of a Body Forcementioning

confidence: 98%

“…We use the approach of Wagner and Yeomans [93] and Bennett [5,6,75] to impose boundary conditions on the hydrodynamic moments u x , u y , and Π xx ,…”

Section: Implementation Of a Body Forcementioning

confidence: 99%

Lattice Boltzmann Formulation for Linear Viscoelastic Fluids Using an Abstract Second Stress

Dellar¹

2014

SIAM J. Sci. Comput.

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The kinetic theory of gases implies an independent evolution equation for the momentum flux tensor that closely resembles an evolution equation for the elastic stress in continuum descriptions of viscoelastic liquids. However, kinetic theory leads to a nonobjective convected derivative for the evolution of the deviatoric stress, and a fixed relation between the stress relaxation rate and the viscosity. We show that simulations of freely decaying shear flow using the standard two-dimensional lattice Boltzmann kinetic model develop a tangential stress consistent with this nonobjective convected derivative, and this fixed relation between parameters. By contrast, viscoelastic liquids are typically modeled by an upper convected derivative, and with two independent parameters for the viscosity and stress relaxation rate. Although we are unable to obtain an upper convected derivative from kinetic theory with a scalar distribution function, we show that introducing a general linear coupling to a second stress tensor yields the linear Jeffreys viscoelastic model with three independent parameters in the incompressible limit. Unlike previous work, we do not attempt to represent the additional stress through moments of additional distribution functions, but treat it only as an abstract tensor that couples to the corresponding tensorial moment of the hydrodynamic distribution functions. This greatly simplifies the derivation, and the implementation of flows driven by body forces. The utility of the approach is demonstrated through simulations of Stokes' second problem for an oscillating boundary, of the four-roller mill, and of three-dimensional Arnold-Beltrami-Childress and Taylor-Green flows.

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“…The Knudsen boundary layers are usually considered in the context of the rarefied gas dynamics as boundary conditions for non-equilibrium flows [1]. A very comprehensive critical review on the efforts devoted to appropriate LBM boundary conditions can be found in works [2,3]. The objective of this work is quite different.…”

Section: Introductionmentioning

confidence: 98%

Local boundary reflections in lattice Boltzmann schemes: Spurious boundary layers and their impact on the velocity, diffusion and dispersion

Ginzburg¹,

Roux²,

Silva³

2015

Comptes Rendus. Mécanique

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This work demonstrates that in advection-diffusion Lattice Boltzmann schemes, the local mass-conserving boundary rules, such as bounce-back and local specular reflection, may modify the transport coefficients predicted by the Chapman-Enskog expansion when they enforce to zero not only the normal, but also the tangential boundary flux. In order to accommodate it to the bulk solution, the system develops a Knudsen-layer correction to the non-equilibrium part of the population solution. Two principal secondary effects-(i) decrease in the diffusion coefficient, and (ii) retardation of the average advection velocity, obtained in a closed analytical form, are proportional, respectively, to freely assigned diagonal weights for equilibrium mass and velocity terms. In addition, due to their transverse velocity gradients, the boundary layers affect the longitudinal diffusion coefficient similarly to Taylor dispersion, as they grow as the square of the Péclet number. These numerical artifacts can be eliminated or reduced by a proper space distribution of the free-tunable collision eigenvalue in two-relaxation-time schemes.

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Lattice Boltzmann simulations of pressure-driven flows in microchannels using Navier–Maxwell slip boundary conditions

Cited by 45 publications

References 55 publications

Analysis and accurate numerical solutions of the integral equation derived from the linearized BGKW equation for the steady Couette flow

Analysis and accurate numerical solutions of the integral equation derived from the linearized BGKW equation for the steady Couette flow

Lattice Boltzmann Formulation for Linear Viscoelastic Fluids Using an Abstract Second Stress

Local boundary reflections in lattice Boltzmann schemes: Spurious boundary layers and their impact on the velocity, diffusion and dispersion

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