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Kinetic Theory for Gases and Plasmas: Lecture 2: Plasma Kinetics. Russel Caflisch IPAM Mathematics Department, UCLA. Review of First Lecture. Velocity distribution function Molecular chaos Boltzmann equation H-theorem (entropy) Maxwellian equilibrium Fluid dynamic limit DSMC
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Kinetic Theory for Gases and Plasmas:Lecture 2: Plasma Kinetics Russel Caflisch IPAM Mathematics Department, UCLA IPAM Plasma Tutorials 2012
Review of First Lecture • Velocity distribution function • Molecular chaos • Boltzmann equation • H-theorem (entropy) • Maxwellian equilibrium • Fluid dynamic limit • DSMC • DSMC becomes computationally intractable near fluid regime, since collision time-scale becomes small IPAM Plasma Tutorials 2012
Where are collisions signifiant in plasmas?Example: Tokamak edge boundary layer Temp. (eV) 1000 500 0 R (cm) Schematic views of divertor tokamak and edge-plasma region (magnetic separatrix is the red line and the black boundaries indicate the shape of magnetic flux surfaces) Edge pedestaltemperature profile near the edge of an H-mode discharge in the DIII-D tokamak. [Porter2000]. Pedestal is shaded region. From G. W. Hammett, review talk 2007 APS Div Plasmas Physics Annual Meeting, Orlando, Nov. 12-16. IPAM Plasma Tutorials 2012
Basics of mathematical (classical) plasma physics IPAM Plasma Tutorials 2012
Gas or Plasma Flow: Kinetic vs. Fluid • Kinetic description • Discrete particles • Motion by particle velocity • Interact through collisions • Fluid (continuum) description • Density, velocity, temperature • Evolution following fluid eqtns (Euler or Navier-Stokes or MHD) When does continuum description fail? IPAM Plasma Tutorials 2012
Debye Length • Charged particles rather than neutrals Electrons: e- FACM 2010
Debye Length • Quasi-neutrality: nearly equal number of oppositely charged particles Electrons: e- Ions: H+ FACM 2010
Debye Length • Pick out a distinguished particle Electrons: e- Ions: H+ FACM 2010
Debye Length • Debye length = range of influence, e.g., for single electron λD Electrons: e- Ions: H+ FACM 2010
Debye Length • In neighborhood of an electron there is deficit of other electrons, suplus of positive ions Electrons: e- Ions: H+ FACM 2010
Debye Length • Replace positive charged particles by continuum, for simplicity Electrons: e- ; test particle ; Ions: smoothed FACM 2010
Debye Length: Derivation • Distribution of electrons and ions • charge q; temperature T; dielectric coeff ε0; • potential φ, energy is -q φ • electrons in Gibbs distribution (in space) • Uniform ions distribution • Poisson equation (linearized) • Single electron at 0 • Solution With length scale λD = Debye length: FACM 2010
Interactions of Charged Particles in a Plasma • Plasma parameter g = (n λD3)-1 • Plasma approximation g<<1 • Many particles in a Debye sphere • Otherwise, the system is an N-body problem • Long range interactions • r > λD (λD = Debye length) • Individual particle interactions are not significant • Interaction mediated by electric and magnetic fields • Short range interactions • r < λD • Coulomb interactions FACM 2010
Levels of Description • Magneto-hydrodynamic (MHD) equations • Equilibrium • Continuum • Vlasov-Maxwell equations • Nonequilibrium • No collisions • Landau-Fokker-Planck equations • Nonequilibrium • Collisions IPAM Plasma Tutorials 2012
MHD Equations Fluid equations with Lorenz force Ohm’s law Maxwell’s equations IPAM Plasma Tutorials 2012
Plasma kinetics IPAM Plasma Tutorials 2012
Vlasov Equations • Velocity distribution function • for each species • Convection • Lorentz force • Collisionless m=mass, q=charge IPAM Plasma Tutorials 2012
Landau Fokker Planck Equation • Velocity distribution function • for each species • Convection • Electromotive force • Collisions m=mass, q=charge IPAM Plasma Tutorials 2012
Coulomb Collisions • Collision of 2 charged particles (i=1,2) with • Position xi, mass mi, charge qi has solution in which • (r,θ) are polar coordinates for x1-x2 • v0 is incoming relative velocity, • b is impact parameter IPAM Plasma Tutorials 2012
Derivation of Fokker-Planck Eqtn • Binary Coulomb collision • (with m1=m2, q1=q2) • relative velocity v0 , displacement b before collision • deflection angle θ • scattering cross section (Rutherford) θ v0 b IPAM 31 March 2009
Landau-Fokker-Planck equation for collisions • Coulomb interactions • collision rate ≈ u-3 for two particles with relative velocity u • Fokker-Planck equation IPAM Plasma Tutorials 2012
Derivation of Fokker-Planck Eqtn • Coulomb collisions are predominantly grazing • Differential collision rate is singular at θ≈0 since • Total collision rate • Aggregate effect of the collisions • measured by the momentum transfer, is • integrand is only marginally singular IPAM 31 March 2009
Derivation of Fokker-Planck Eqtn • Debye cutoff • Screened potential is • Approximate the effect of screening by cutoff in angle • Cross section for momentum transfer is • Corresponding Boltzmann collision operator Qλhas collision rate IPAM 31 March 2009
Derivation of Fokker-Planck Eqtn • Analysis of Alexandre & Villani • “On the Landau approximation in plasma physics” Ann. I. H. Poincaré – AN 21 (2004) 61–95. • Boltzmann eqtn without Lorentz force • Rescale (x,t) → (c/log Λ) (x’,t’) and drop ’, • to obtain • As Λ→∞, • total angular cross section for momentum transfer goes to c|v-w|-3 • all collisions become grazing collisions • the scaled Boltzmann collision operator converges to the Landau-Fokker –Planck collision operator IPAM 31 March 2009
Derivation of Fokker-Planck Eqtn • Scaling of Alexandre & Villani • They find that the relevant time scale T and space scale X are is • On this time and space scale, they prove that solution of the Boltzmann equation (without Lorentz force) converges to a solution of the LFP equation IPAM 31 March 2009
Derivation of Fokker-Planck Eqtn • Scaling difficulty • Alexandre and Villani are unable to find a scaling such that both the LFP collision operator and the Lorentz force terms are significant • On a scale for which the Lorentz force is O(1), the collision term is insignificant IPAM 31 March 2009
Collisions in Gases vs. Plasmas • Collisions between velocities v and v* • Gas collisions • hard spheres, σ = cross section area of sphere • collision rate is σ| v - v* | • any two velocities can collide → smoothing in v • Plasma (Coulomb) collisions • very long range, potential O(1/r) • collisions are grazing, localized as in Landau eqtn • Collision rate | v - v* |-3 small for well separated velocities • differential eqtn in v, as well as x,t • waves in phase space • Landau damping (interaction between waves and particles) IPAM Plasma Tutorials 2012
Comparison F-P to Boltzmann • Boltzmann • collisions are single physical collisions • total collision rate for velocity v is ∫|v-v’| σ(|v-v’| ) f(v’) dv’ • FP • actual collision rate is infinite due to long range interactions: σ = (sin θ)-4 • FP “collisions” are each aggregation of many small deflections • described as drift and diffusion in velocity space IPAM 31 March 2009
Simulation methods IPAM Plasma Tutorials 2012
Monte Carlo Particle Methods for Coulomb Interactions • Particle-field representation • Mannheimer, Lampe & Joyce, JCP 138 (1997) • Particles feel drag from Fd = -fd (v)v and diffusion of strength σ = σ(D) • numerical solution of SDE, with Milstein correction • Lemons et al., J Comp Phys 2008 • Particle-particle representation • Takizuka & Abe, JCP 25 (1977), Nanbu. Phys. Rev. E. 55 (1997) Bobylev & Nanbu Phys. Rev. E. 61 (2000) • Binary particle “collisions”, from collision integral interpretation of FP equation IPAM 31 March 2009
Binary Collision Methods for LFP • Bobylev-Nanbu (PRE 2000) • Implicit-like transformation of LFP over a single time step • Expansion of scattering operator in spherical harmonics • Approximation at O(Δt) with tractable binary collision interpretation • Resulting binary collisions • Every particle collides once per time step • Collisions depend on Δt IPAM Plasma Tutorials 2012
Bobylev-Nanbu Analysis • Boltzmann eqtn, as scattering operator in which IPAM Plasma Tutorials 2012
Implicit-like transformation • First order approximation • “Implicit” approximation • Optimal choice of ε • Result • Every particle collides once in every time step IPAM Plasma Tutorials 2012
Transformation to Tractable Binary Form • Implicit-like formulation • with (for Landau-Fokker-Planck) • D is an expansion in Legendre polynomials in |u| u·n • D can be greatly simplified by approximation at O(Δt) IPAM Plasma Tutorials 2012
Takizuka & Abe Method • T. Takizuka & H. Abe, J. Comp. Phys. 25 (1977). • T & A binary collision model is equivalent to the collision term in Landau-Fokker-Planck equation • The scattering angle θ is chosen randomly from a Gaussian random variable δ • δ has mean 0 and variance • Parameters • Log Λ = Coulomb logarithm • u = relative velocity • Simulation • Every particle collides once in each time interval • Scattering angle depends on dt • cf. DSMC for RGD: each particle has physical number of collisions • Implemented in ICEPIC by Birdsall, Cohen and Proccaccia • Numerical convergence analysis by Wang, REC, etal. (2007) O(dt1/2). IPAM 31 March 2009
Nanbu’s Method • Combine many small-angle collisions into one aggregate collision • K. Nanbu. Phys. Rev. E. 55 (1997) • Scattering in time step dt • χN = cumulative scattering angle after N collisions • N-independent scattering parameter s • Aggregation is only for collisions between two given particle velocities • Steps to compute cumulative scattering angle: • At the beginning of the time step, calculate s • Determine A from • Probability that postcollison relative velocity is scattered into dΩ is • Implemented in ICEPIC by Wang & REC -- simulation - theory IPAM 31 March 2009
Simulation for Plasmas:Test Cases • Relaxation of an anisotropic Maxwellian • Bump-on-tail • Sheath • Two stream instability • Computations using Nanbu’s method and hybrid method IPAM Plasma Tutorials 2012
Numerical Test Case:Relaxation of Anisotropic Distribution • Specification • Initial distribution is Maxwellian with anisotropic temperature • Single collision type: electron-electron (e-e) or electron-ion (e-i). • Spatially homogeneous. • The figure at right shows the time relaxation of parallel and transverse temperatures. • All reported results are for e-e; similar results for e-i. • Approximate analytic solution of Trubnikov (1965). IPAM 31 March 2009
Hybrid Method for Bump-on-Tail FACM 2010
Hybrid Method Using Fluid Solver • Improved method for spatial inhomogeneities • Combines fluid solver with hybrid method • previous results used Boltzmann type fluid solver • Euler equations with source and sink terms from therm/detherm • application to electron sheath (below) • potential (left), electric field (right) FACM 2010
Conclusions and Prospects • Landau Fokker Planck collision operator • Infinite rate of grazing interactions → finite rate of aggregate collisions • Monte Carlo simulation methods for kinetics have trouble in the fluid and near-fluid regime • Math leading to new methods that are robust in fluid limit IPAM Plasma Tutorials 2012