Papers
Topics
Authors
Recent
Assistant
AI Research Assistant
Well-researched responses based on relevant abstracts and paper content.
Custom Instructions Pro
Preferences or requirements that you'd like Emergent Mind to consider when generating responses.
Gemini 2.5 Flash
Gemini 2.5 Flash 178 tok/s
Gemini 2.5 Pro 50 tok/s Pro
GPT-5 Medium 38 tok/s Pro
GPT-5 High 40 tok/s Pro
GPT-4o 56 tok/s Pro
Kimi K2 191 tok/s Pro
GPT OSS 120B 445 tok/s Pro
Claude Sonnet 4.5 36 tok/s Pro
2000 character limit reached

Phase space eigenfunctions with applications to continuum kinetic simulations (2402.02180v2)

Published 3 Feb 2024 in physics.plasm-ph

Abstract: Continuum kinetic simulations are increasingly capable of resolving high-dimensional phase space with advances in computing. These capabilities can be more fully explored by using linear kinetic theory to initialize the self-consistent field and phase space perturbations of kinetic instabilities. The phase space perturbation of a kinetic eigenfunction in unmagnetized plasma has a simple analytic form, and in magnetized plasma may be well approximated by truncation of a cyclotron-harmonic expansion. We catalogue the most common use cases with a historical discussion of kinetic eigenfunctions and by conducting nonlinear Vlasov-Poisson and Vlasov-Maxwell simulations of single- and multi-mode two-stream, loss-cone, and Weibel instabilities in unmagnetized and magnetized plasmas with one- and two-dimensional geometries. Applications to quasilinear kinetic theory are discussed and applied to the bump-on-tail instability. In order to compute eigenvalues we present novel representations of the dielectric function for ring distributions in magnetized plasmas with power series, hypergeometric, and trigonometric integral forms. Eigenfunction phase space fluctuations are visualized for prototypical cases such as the Bernstein modes to build intuition. In addition, phase portraits are presented for the magnetic well associated with nonlinear saturation of the Weibel instability, distinguishing current-density-generating trapping structures from charge-density-generating ones.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (112)
  1. An Energy Conserving Vlasov Solver That Tolerates Coarse Velocity Space Resolutions: Simulation of MMS Reconnection Events. Journal of Geophysical Research: Space Physics, 127(2):e2021JA029976. e2021JA029976 2021JA029976.
  2. Balescu, R. (1997). Statistical dynamics: matter out of equilibrium. World Scientific.
  3. Finite spatial-grid effects in energy-conserving particle-in-cell algorithms. Computer Physics Communications, 258:107560.
  4. Bernstein, I. B. (1958). Waves in a plasma in a magnetic field. Physical Review, 109(1):10.
  5. Nonlinear electron plasma oscillation: the “water bag model”. Physics Letters A, 28(1):68–69.
  6. Plasma Physics via Computer Simulation. Series in Plasma Physics and Fluid Dynamics. Taylor & Francis.
  7. Theory of plasma oscillations. A. Origin of medium-like behavior. Phys. Rev., 75.
  8. Boyd, J. P. (2001). Chebyshev and Fourier spectral methods. Courier Corporation.
  9. Aspects of linear Landau damping in discretized systems. Physics of Plasmas, 20(2):022108.
  10. Nonlinear saturation of the Weibel instability. Physics of Plasmas, 24(11):112116.
  11. Spatial structure and time evolution of the Weibel instability in collisionless inhomogeneous plasmas. Physical review E, 56(1):963.
  12. Case, K. M. (1959). Plasma oscillations. Annals of physics, 7(3):349–364.
  13. Che, H. (2016). Electron two-stream instability and its application in solar and heliophysics. Modern Physics Letters A, 31(19):1630018.
  14. The integration of the Vlasov equation in configuration space. Journal of Computational Physics, 22(3):330–351.
  15. High-dimensional sparse Fourier algorithms. Numerical Algorithms, 87:161–186.
  16. Survey of theories of anomalous transport. Plasma physics and controlled fusion, 36(5):719.
  17. Crews, D. W. (2022). Numerical simulation of collisionless kinetic plasma turbulence. PhD thesis, University of Washington.
  18. The Kadomtsev Pinch Revisited for Sheared-Flow-Stabilized Z-Pinch Modeling. IEEE Transactions on Plasma Science, pages 1–13.
  19. On the validity of quasilinear theory applied to the electron bump-on-tail instability. Physics of Plasmas, 29(4):043902.
  20. Electromagnetic extension of the Dory–Guest–Harris instability as a benchmark for Vlasov–Maxwell continuum kinetic simulations of magnetized plasmas. Physics of Plasmas, 28(7):072112.
  21. Computationally efficient high-fidelity plasma simulations by coupling multi-species kinetic and multi-fluid models on decomposed domains. Journal of Computational Physics, 483:112073.
  22. Kinetic description of high intensity beam propagation through a periodic focusing field based on the nonlinear Vlasov-Maxwell equations. Part. Accel., 59:175–250.
  23. Nonlinear development of electromagnetic instabilities in anisotropic plasmas. The Physics of Fluids, 15(2):317–333.
  24. Shear-induced pressure anisotropization and correlation with fluid vorticity in a low collisionality plasma. Monthly notices of the royal astronomical society, 475(1):181–192.
  25. Dodin, I. Y. (2022). Quasilinear theory for inhomogeneous plasma. Journal of Plasma Physics, 88(4):905880407.
  26. Correction to the Alfvén-Lawson criterion for relativistic electron beams. Physics of Plasmas, 13(10):103104.
  27. Unstable electrostatic plasma waves propagating perpendicular to a magnetic field. Physical Review Letters, 14(5):131.
  28. Anomalous Diffusion Arising from Microinstabilities in a Plasma. The Physics of Fluids, 5(12):1507–1513.
  29. Thermodynamic approach to the interpretation of self-consistent pressure profiles in a tokamak. Plasma Physics Reports, 41:685–695.
  30. Einkemmer, L. (2019). A performance comparison of semi-Lagrangian discontinuous Galerkin and spline based Vlasov solvers in four dimensions. Journal of Computational Physics, 376:937–951.
  31. Escande, D. F. (2016). Contributions of plasma physics to chaos and nonlinear dynamics. Plasma Physics and Controlled Fusion, 58(11):113001.
  32. Collisionless relaxation of a Lynden-Bell plasma. Journal of Plasma Physics, 88(5):925880501.
  33. Filamentation instability of counterstreaming laser-driven plasmas. Physical review letters, 111(22):225002.
  34. The plasma dispersion function: the Hilbert transform of the Gaussian. Academic press.
  35. The geometric theory of charge conservation in particle-in-cell simulations. Journal of Plasma Physics, 86(3):835860303.
  36. Table of Integrals, Series, and Products. Academic Press, Seventh edition.
  37. Griffiths, D. J. (2012). Resource Letter EM-1: Electromagnetic Momentum. American Journal of Physics, 80(1):7–18.
  38. Introduction to plasma physics: With space, laboratory and astrophysical applications. Cambridge University Press.
  39. Alias-Free, Matrix-Free, and Quadrature-Free Discontinuous Galerkin Algorithms for (Plasma) Kinetic Equations. In SC20: International Conference for High Performance Computing, Networking, Storage and Analysis, pages 1–15.
  40. Hamiltonian particle-in-cell methods for Vlasov-Maxwell equations. Physics of Plasmas, 23(9):092108.
  41. A discontinuous Galerkin method for the Vlasov–Poisson system. Journal of Computational Physics, 231(4):1140–1174.
  42. An integral transform technique for kinetic systems with collisions. Physics of Plasmas, 25(8):082118.
  43. Nodal discontinuous Galerkin methods: algorithms, analysis, and applications. Springer Science & Business Media.
  44. Beam-Weibel filamentation instability in near-term and fast-ignition experiments. Physics of plasmas, 12(8):082304.
  45. Physics-based-adaptive plasma model for high-fidelity numerical simulations. Frontiers in Physics, 6:105.
  46. Astrophysical Gyrokinetics: Basic Equations and Linear Theory. The Astrophysical Journal, 651(1):590.
  47. Gyrokinetic Simulations of Solar Wind Turbulence from Ion to Electron Scales. Phys. Rev. Lett., 107:035004.
  48. Observation of magnetic field generation via the Weibel instability in interpenetrating plasma flows. Nature Physics, 11(2):173–176.
  49. Hutchinson, I. H. (2020). Particle trapping in axisymmetric electron holes. Journal of Geophysical Research: Space Physics, 125(8):e2020JA028093.
  50. Hutchinson, I. H. (2021). Synthetic multidimensional plasma electron hole equilibria. Physics of Plasmas, 28(6):062306.
  51. Ichimaru, S. (1992). Statistical Plasma Physics, Volume I: Basic Principles. CRC Press.
  52. Discontinuous Galerkin algorithms for fully kinetic plasmas. Journal of Computational Physics, 353:110–147.
  53. Wave dispersion in the hybrid-Vlasov model: Verification of Vlasiator. Physics of Plasmas, 20(11):112114.
  54. Gempic: geometric electromagnetic particle-in-cell methods. Journal of Plasma Physics, 83(4):905830401.
  55. Landau, L. D. (1946). On the vibrations of the electronic plasma. J. Phys. USSR, 10(26).
  56. Electrodynamics of continuous media. Pergamon press Oxford.
  57. Plasma oscillations with diffusion in velocity space. Physical Review, 112(5):1456.
  58. Lerche, I. (1974). A note on summing series of Bessel functions occurring in certain plasma astrophysical situations. Astrophysical Journal, Vol. 190, pp. 165-166 (1974), 190:165–166.
  59. Leubner, M. P. (2004). Fundamental issues on kappa-distributions in space plasmas and interplanetary proton distributions. Physics of Plasmas, 11(4):1308–1316.
  60. A general kinetic mirror instability criterion for space applications. Journal of Geophysical Research: Space Physics, 106(A7):12993–12998.
  61. Entropy defect in thermodynamics. Scientific Reports, 13(1):9033.
  62. Mace, R. L. (2004). Generalized electron Bernstein modes in a plasma with a kappa velocity distribution. Physics of Plasmas, 11(2):507–522.
  63. A new formulation and simplified derivation of the dispersion function for a plasma with a kappa velocity distribution. Physics of Plasmas, 16(7):072113.
  64. Sheared-flow generalization of the Harris sheet. Physics of Plasmas, 7(4):1287–1293.
  65. Morrison, P. J. (2000). Hamiltonian description of vlasov dynamics: action-angle variables for the continuous spectrum. Transport theory and statistical physics, 29(3-5):397–414.
  66. Morrison, P. J. (2017). Structure and structure-preserving algorithms for plasma physics. Physics of Plasmas, 24(5):055502.
  67. Dielectric energy versus plasma energy, and Hamiltonian action-angle variables for the Vlasov equation. Physics of Fluids B: Plasma Physics, 4(10):3038–3057.
  68. Numerical simulation of the Weibel instability in one and two dimensions. The Physics of Fluids, 14(4):830–840.
  69. On Landau damping. Acta Mathematica, 207(1):29 – 201.
  70. Newberger, B. S. (1982). New sum rule for products of Bessel functions with application to plasma physics. Journal of Mathematical Physics, 23(7):1278–1281.
  71. Kinetic eigenmodes and discrete spectrum of plasma oscillations in a weakly collisional plasma. Physical review letters, 83(10):1974.
  72. Complete spectrum of kinetic eigenmodes for plasma oscillations in a weakly collisional plasma. Phys. Rev. Lett., 92:065002.
  73. Drift Instabilities in Thin Current Sheets Using a Two-Fluid Model With Pressure Tensor Effects. Journal of Geophysical Research: Space Physics, 124(5):3331–3346.
  74. Nicholson, D. R. (1983). Introduction to plasma theory. Wiley New York.
  75. Vlasov methods in space physics and astrophysics. Living Reviews in Computational Astrophysics, 4(1):1.
  76. Kinetic instability of whistlers in electron beam-plasma systems. Physics of Plasmas, 31(3):032117.
  77. Penrose, O. (1960). Electrostatic Instabilities of a Uniform Non‐Maxwellian Plasma. The Physics of Fluids, 3(2):258–265.
  78. Geometric Particle-in-Cell Simulations of the Vlasov–Maxwell System in Curvilinear Coordinates. SIAM Journal on Scientific Computing, 43(1):B194–B218.
  79. ViDA: a Vlasov–DArwin solver for plasma physics at electron scales. Journal of Plasma Physics, 85(5):905850506.
  80. Kappa distributions: Theory and applications in space plasmas. Solar physics, 267:153–174.
  81. Mirror instability at finite ion-Larmor radius wavelengths. Journal of Geophysical Research: Space Physics, 109(A9).
  82. Linear theory of the mirror instability in non-Maxwellian space plasmas. Journal of Geophysical Research: Space Physics, 107(A10):SMP–18.
  83. High‐Frequency Electrostatic Plasma Instability Inherent to “Loss‐Cone” Particle Distributions. The Physics of Fluids, 8(3):547–550.
  84. Spectral Approach to Plasma Kinetic Simulations Based on Hermite Decomposition in the Velocity Space. Frontiers in Astronomy and Space Sciences, 5.
  85. Strong Langmuir turbulence. Physics Reports, 40(1):1–73.
  86. Schamel, H. (2023). Pattern formation in Vlasov–Poisson plasmas beyond Landau caused by the continuous spectra of electron and ion hole equilibria. Reviews of Modern Plasma Physics, 7(1):11.
  87. Wave propagation along an arbitrary direction in a bi-maxwellian plasma. Plasma Physics, 18(2):95.
  88. Damping of perturbations in weakly collisional plasmas. Physics of Plasmas, 9(8):3245–3253.
  89. Conditions for the onset of the current filamentation instability in the laboratory. Journal of Plasma Physics, 84(3).
  90. Advanced physics calculations using a multi-fluid plasma model. Computer Physics Communications, 182(9):1767–1770. Computer Physics Communications Special Edition for Conference on Computational Physics Trondheim, Norway, June 23-26, 2010.
  91. Temperature-dependent Saturation of Weibel-type Instabilities in Counter-streaming Plasmas. The Astrophysical Journal Letters, 872(2):L28.
  92. Second-Order Effects in the Weibel Instability. Physical Review Letters, 29(26):1729.
  93. Cyclotron harmonic wave propagation and instabilities: I. Perpendicular propagation. Journal of Plasma Physics, 4(2):231–248.
  94. Cyclotron harmonic wave propagation and instabilities: II. Oblique propagation. Journal of Plasma Physics, 4(2):249–264.
  95. Space-charge effects in the current-filamentation or Weibel instability. Physical review letters, 96(10):105002.
  96. A hybrid-Vlasov model based on the current advance method for the simulation of collisionless magnetized plasma. Journal of Computational Physics, 225(1):753–770.
  97. van Kampen, N. G. (1955). On the theory of stationary waves in plasmas. Physica, 21(6-10):949–963.
  98. Vedenov, A. A. (1963). Quasi-linear plasma theory (theory of a weakly turbulent plasma). Journal of Nuclear Energy. Part C, Plasma Physics, Accelerators, Thermonuclear Research, 5(3):169.
  99. SpectralPlasmaSolver: a Spectral Code for Multiscale Simulations of Collisionless, Magnetized Plasmas. Journal of Physics: Conference Series, 719(1):012022.
  100. Nonlinear energy transfer and current sheet development in localized Alfvén wavepacket collisions in the strong turbulence limit. Journal of Plasma Physics, 84(1):905840103.
  101. Collisionless isotropization of the solar-wind protons by compressive fluctuations and plasma instabilities. The Astrophysical Journal, 831(2):128.
  102. On Kinetic Slow Modes, Fluid Slow Modes, and Pressure-balanced Structures in the Solar Wind. The Astrophysical Journal, 840(2):106.
  103. Conservative fourth-order finite-volume Vlasov–Poisson solver for axisymmetric plasmas in cylindrical phase space coordinates. Journal of Computational Physics, 373:877–899.
  104. Dory–Guest–Harris instability as a benchmark for continuum kinetic Vlasov–Poisson simulations of magnetized plasmas. Journal of Computational Physics, 277:101–120.
  105. Vlasov simulations of kinetic Alfvén waves at proton kinetic scales. Physics of Plasmas, 21(11):112107.
  106. Exploring phase space turbulence in magnetic fusion plasmas. Journal of Physics: Conference Series, 510(1):012045.
  107. Weibel, E. S. (1959). Spontaneously Growing Transverse Waves in a Plasma Due to an Anisotropic Velocity Distribution. Phys. Rev. Lett., 2:83–84.
  108. The Fluid-like and Kinetic Behavior of Kinetic Alfvén Turbulence in Space Plasma. The Astrophysical Journal, 870(2):106.
  109. Yoon, P. H. (2007). Spontaneous thermal magnetic field fluctuation. Physics of plasmas, 14(6).
  110. Quasi-linear theory of anomalous resistivity. Journal of Geophysical Research: Space Physics, 111(A2).
  111. Quantifying Wave–Particle Interactions in Collisionless Plasmas: Theory and Its Application to the Alfvén-mode Wave. The Astrophysical Journal, 930(1):95.
  112. Zhdankin, V. (2023). Dimensional measures of generalized entropy. Journal of Physics A: Mathematical and Theoretical, 56(38):385002.
Citations (1)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
Dice Question Streamline Icon: https://streamlinehq.com

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now
Lightbulb Streamline Icon: https://streamlinehq.com

Continue Learning

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Authors (2)

  1. D. W. Crews
  2. U. Shumlak
List To Do Tasks Checklist Streamline Icon: https://streamlinehq.com

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up
X Twitter Logo Streamline Icon: https://streamlinehq.com

Tweets

This paper has been mentioned in 1 tweet and received 0 likes.

Upgrade to Pro to view all of the tweets about this paper:

Start a free 7-day Pro trial