Boundary-value problems of the Boltzmann equation: Asymptotic and numerical analyses (Part 2) Kazuo Aoki Dept. of Mech. Eng. and Sci. Kyoto University.

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Presentation transcript:

Boundary-value problems of the Boltzmann equation: Asymptotic and numerical analyses (Part 2) Kazuo Aoki Dept. of Mech. Eng. and Sci. Kyoto University Intensive Lecture Series (Postech, June 20-21, 2011)

Near continuum regime (small Knudsen number): Asymptotic theory

Strouhal number Knudsen number Dimensionless variables Navier-Stokes + Slip conditions ? Steady (time-independent) flows Systematic asymptotic analysis (formal) for small Kn Y. Sone (1969, 1971, …, 2002, … 2007, …) Kinetic Theory and Fluid Dynamics (Birkhäuser, 2002) Molecular Gas Dynamics: Theory, Techniques, and Applications (Birkhäuser, 2007) Fluid-dynamic description

Asymptotic analysis (brief summary) Fluid-dynamic solution Boltzmann eq. (dimensionless) + BC (Hilbert expansion) Macroscopic quantities Boltzmann eq. Sequence of integral equations Solutions Constraints for Fluid-dynamic equations

Knudsen layers F-D sol.Knudsen-layer correction Half-space problems of linearized Boltzmann equation Boundary conditions for fluid-dynamic equations Constraints on boundary values of gas **************** Types of F-D system (eqs. + bc) are different depending on physical situations

charct. speed sound speed charct. density viscosity (temp. & density variations) small large Stokes Incomp. N-S Ghost effect Euler m.f.p characteristic length Parameter relation

charct. density viscosity (temp. & density variations) small large Stokes Incomp. N-S Ghost effect Euler m.f.p characteristic length Parameter relation charct. speed sound speed

Sone (1969, 1971), RGD6, RGD7 Sone (1991), Advances in Kinetic Theory and Continuum Mechanics F-D eqs. Stokes system Stokes limit Golse & Levermore (2002) CPAM 55, 336 * * * * * Small temperature & density variations Starting point: Linearized Boltzmann eq.

F-D eqs. Stokes system BC No-slip condition Slip condition slip coefficients

Effects of curvature, thermal stress, … Thermal creep Temp. jump Shear slip

Thermal creep fast slow Diffuse reflection: isotropic Gas at rest (no pressure gradient)

Thermal creep fast slow flow Diffuse reflection: isotropic Gas at rest (no pressure gradient)

charct. density viscosity (temp. & density variations) small large Stokes Incomp. N-S Ghost effect Euler m.f.p characteristic length Parameter relation charct. speed sound speed

Sone, A, Takata, Sugimoto, & Bobylev (1996), Phys. Fluids 8, 628 Large temperature & density variations Ghost effect Defect of classical fluid dynamics gas Boltzmann equation (hard-sphere molecules) Diffuse reflection Boundary at rest, no flow at infinity (more generally, slow motion of boundary and slow flow at infinity can be included) Example

Dimensionless variables (normalized by ) Boltzmann equation Boundary condition dimensionless molecular velocity Formal asymptotic analysis for

Boltzmann eqs. Hilbert solution (expansion) Macroscopic quantities Sequence of integral equations Fluid-dynamic-type equations

Sequence of integral equations Zeroth-order Solution: local Maxwellian Assumption Boundary at rest (No flow at infinity) Consistent assumption

Higher-order Homogeneous eq. has nontrivial solutions Linearized collision operator Kernel of Solution: Solvability conditions Fluid-dynamic equations

Fluid-dynamic-type system for gas

F-D eqs. const for hard-sphere molecules

BC can be made to satisfy BC at if Knudsen layer and slip boundary conditions However, higher-order solutions cannot satisfy kinetic BC Knudsen layer

Hilbert solution Knudsen-layer correction Stretched normal coordinate Solution: Eq. and BC for Half-space problem for linearized Boltzmann eq.

Knudsen-layer problem Solution exists uniquely iff take special values Undetermined consts. Boundary values of Grad (1969) Conjecture Bardos, Caflisch, & Nicolaenko (1986): CPAM Maslova (1982), Cercignani (1986) Golse, Poupaud (1989)

BC 0 0 Thermal creep Thermal creep flow caused by large temperature variation Flow caused by thermal stress Galkin, Kogan, & Fridlander (71)

Example Thermal creep flow in 2D channel with sinusoidal boundary and with sinusoidal temperature distribution Laneryd, A, Degond, & Mieussens (2006), RGD25 Some results for Numerical sol. by finite- volume method hard-sphere molecules

Arrows A type of Knudsen pump One-way flow with pumping effect

Arrows A type of Knudsen pump One-way flow with pumping effect

: Isothermal lines

Large temperature & density variations Ghost effect Defect of classical fluid dynamics Fluid- dynamic limit F-D system for gas Sone, A, Takata, Sugimoto, & Bobylev (1996), Phys. Fluids 8, 628

F-D eqs. const for hard-sphere molecules

BC 0 0 Thermal creep

Continuum (fluid-dynamic) limit Navier-Stokes system gas The flow vanishes; however, the temperature field is still affected by the invisible flow Ghost effect : steady heat-conduction eq. + no-jump cond. Defect of Navier-Stokes system

Single gas: Sone, A, Takata, Sugimoto, & Bobylev (1996), Phys. Fluids 8, 628 Sone, Takata, & Sugimoto (1996), Phys. Fluids 8, 3403 Sone (1997), Rarefied Gas Dynamics (Peking Univ. Press), p. 3 Sone (2000), Ann. Rev. Fluid Mech. 32, 779 Sone & Doi (2003), Phys. Fluids 15, 1405 Sone, Handa, & Doi (2003), Phys. Fluids 15, 2904 Sone and Doi (2004), Phys. Fluids 16, 952 Sone & Doi (2005), Rarefied Gas Dynamics (AIP), p. 258 References for ghost effect Gas mixture: Takata & A (1999), Phys. Fluids 11, 2743 Takata & A (1999), Rarefied Gas Dynamics (Cepadues), Vol. 1, p. 479 Takata & A (2001), Transp. Theory Stat. Phys. 30, 205 Takata (2004), Phys. Fluids 16 Yoshida & A (2006), Phys. Fluids 18,

Isothermal lines Arrows : asymptotic : N-S