Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
144 tokens/sec
GPT-4o
7 tokens/sec
Gemini 2.5 Pro Pro
46 tokens/sec
o3 Pro
4 tokens/sec
GPT-4.1 Pro
38 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

Electron-only reconnection and ion heating in 3D3V hybrid-Vlasov plasma turbulence (2405.16686v2)

Published 26 May 2024 in physics.plasm-ph

Abstract: We perform 3D3V hybrid-Vlasov simulations of turbulence with quasi-isotropic, compressible injection near ion scales to mimic the Earth's magnetosheath plasma, and investigate the novel electron-only reconnection, recently observed by the NASA's MMS mission, and its impact on ion heating. Retaining electron inertia in the generalized Ohm s law enables collisionless magnetic reconnection. Spectral analysis shows a shift from kinetic Alfv\'en waves (KAW) to inertial kinetic Alfv\'en (IKAW) and inertial whistler waves (IWW) near electron scales. To distinguish the roles of inertial scale and gyroradius ($d_{\rm{i}}$ and $\rho_{\rm{i}}$), three ion beta ($\beta_{\rm{i}} = 0.25, 1, 4$) values are studied. Ion-electron decoupling increases with $\beta_{\rm{i}}$, as ions become less mobile when the injection scale is closer to $\rho_{\rm{i}}$ than $d_{\rm{i}}$, highlighting the role of $\rho_{\rm{i}}$ in achieving an electron magnetohydrodynamic (EMHD) regime at sub-ion scales. This regime promotes electron-only reconnection in turbulence with small-scale injection at $\beta_{\rm{i}} \gtrsim 1$. We observe significant ion heating even at large $\beta_{\rm{i}}$, with $Q_{\rm{i}}/\epsilon \approx 69\%, 91\%, 96\%$ at $\beta_{\rm{i}} = 0.25, 1, 4$ respectively. While ion heating is anisotropic at $\beta_{\rm{i}} \leq 1$ ($T_{\rm i,\perp} > T_{\rm i,\parallel}$), it is marginally anisotropic at $\beta_{\rm{i}} > 1$ ($T_{\rm i,\perp} \gtrsim T_{\rm i,\parallel}$). These findings have implications for other collisionless astrophysical environments, like high-$\beta$ plasmas in intracluster medium, where processes such as micro-instabilities or shocks may inject energy near ion-kinetic scales.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (79)
  1. Solar Wind Turbulence and the Role of Ion Instabilities. Space Sci. Rev., 178:101–139.
  2. Universality of Solar-Wind Turbulent Spectrum from MHD to Electron Scales. PhRvL, 103(16):165003.
  3. Statistical properties of turbulent fluctuations associated with electron-only magnetic reconnection. A&A, 642:A45.
  4. Hybrid-kinetic Simulations of Ion Heating in Alfvénic Turbulence. ApJ, 879(1):53.
  5. Kinetic turbulence in collisionless high-β𝛽\betaitalic_β plasmas. Phys. Rev. X, 13:021014.
  6. Parallel and oblique firehose instability thresholds for bi-kappa distributed protons. Journal of Geophysical Research (Space Physics), 121(4):2842–2852.
  7. Magnetic Fluctuation Power Near Proton Temperature Anisotropy Instability Thresholds in the Solar Wind. Phys. Rev. Lett., 103(21):211101.
  8. Interplay of turbulence and proton-microinstability growth in space plasmas. Physics of Plasmas, 29(10):102107.
  9. Barnes, A. (1966). Collisionless Damping of Hydromagnetic Waves. Physics of Fluids, 9(8):1483–1495.
  10. Asymptotic scalings of fluid, incompressible “electron-only” reconnection instabilities: Electron-magnetohydrodynamics tearing modes. Physics of Plasmas, 30(7):072111.
  11. Geospace environmental modeling (gem) magnetic reconnection challenge. Journal of Geophysical Research: Space Physics, 106(A3):3715–3719.
  12. Spectrum of Kinetic-Alfvén Turbulence. ApJ, 758:L44.
  13. Coexistence of Plasmoid and Kelvin-Helmholtz Instabilities in Collisionless Plasma Turbulence. ApJ, 929(1):62.
  14. Astrophysical Hydromagnetic Turbulence. Space Sci. Rev., 178(2-4):163–200.
  15. The Solar Wind as a Turbulence Laboratory. LRSP, 10.
  16. Electron-only reconnection in plasma turbulence. , 8:317.
  17. Coherent structure formation and magnetic field line reconnection in magnetohydrodynamic turbulence. , 2:1487–1496.
  18. On Stochastic Heating and Its Phase-space Signatures in Low-beta Kinetic Turbulence. ApJ, 916(2):120.
  19. Reconnection and small-scale fields in 2D-3V hybrid-kinetic driven turbulence simulations. , 19(2):025007.
  20. Space-filter techniques for quasi-neutral hybrid-kinetic models. Physics of Plasmas, 27(8):082102.
  21. Plasma turbulence at ion scales: a comparison between particle in cell and Eulerian hybrid-kinetic approaches. \jpp, 83(2):705830202.
  22. Kinetic plasma turbulence: recent insights and open questions from 3D3V simulations. , 6:64.
  23. Turbulent Regimes in Collisions of 3D Alfvén-wave Packets. ApJ, 939(1):36.
  24. Kinetic Cascade in Solar-wind Turbulence: 3D3V Hybrid-kinetic Simulations with Electron Inertia. ApJ, 846:L18.
  25. Perpendicular Ion Heating by Low-frequency Alfvén-wave Turbulence in the Solar Wind. ApJ, 720(1):503–515.
  26. Nature of Kinetic Scale Turbulence in the Earth’s Magnetosheath. ApJ, 842:122.
  27. Multi-species Measurements of the Firehose and Mirror Instability Thresholds in the Solar Wind. ApJ, 825(2):L26.
  28. Magnetohydrodynamic Turbulence in the Plasmoid-mediated Regime. ApJ, 854:103.
  29. Fully kinetic simulations of undriven magnetic reconnection with open boundary conditions. Physics of Plasmas, 13(7):072101.
  30. Role of the Plasmoid Instability in Magnetohydrodynamic Turbulence. Phys. Rev. Lett., 121(16):165101.
  31. Reconnection-driven energy cascade in magnetohydrodynamic turbulence. Science Advances, 8(49):eabn7627.
  32. Bridging hybrid- and full-kinetic models with Landau-fluid electrons. I. 2D magnetic reconnection. A&A, 653:A156.
  33. Magnetic Reconnection as a Driver for a Sub-ion-scale Cascade in Plasma Turbulence. ApJ, 850:L16.
  34. Solar wind turbulent cascade from mhd to sub-ion scales: Large-size 3d hybrid particle-in-cell simulations. ApJ, 853(1):26.
  35. Anisotropic electron heating in turbulence-driven magnetic reconnection in the near-sun solar wind. The Astrophysical Journal, 936(1):27.
  36. A generation mechanism of electrostatic waves and subsequent electron heating in the plasma sheet–lobe boundary region during magnetic reconnection. Journal of Geophysical Research: Space Physics, 111(A9).
  37. Fully Kinetic Simulation of 3D Kinetic Alfvén Turbulence. Phys. Rev. Lett., 120(10):105101.
  38. Reconnection rate and transition from ion-coupled to electron-only reconnection. The Astrophysical Journal, 958(2):172.
  39. Solar wind proton temperature anisotropy: Linear theory and WIND/SWE observations. Geophys. Res. Lett., 33:L09101.
  40. Particle-in-cell simulations of three-dimensional collisionless magnetic reconnection. Journal of Geophysical Research: Space Physics, 106(A12):29831–29841.
  41. Generation of the fast solar wind: A review with emphasis on the resonant cyclotron interaction. Journal of Geophysical Research (Space Physics), 107(A7):1147.
  42. Howes, G. G. (2010). A prescription for the turbulent heating of astrophysical plasmas. MNRAS, 409(1):L104–L108.
  43. Howes, G. G. (2015). The inherently three-dimensional nature of magnetized plasma turbulence. Journal of Plasma Physics, 81(2):325810203.
  44. Electron-only reconnection in an ion-scale current sheet at the magnetopause. The Astrophysical Journal, 922(1):54.
  45. Turbulent Magnetohydrodynamic Reconnection Mediated by the Plasmoid Instability. ApJ, 818:20.
  46. Thermal disequilibration of ions and electrons by collisionless plasma turbulence. , 116(3):771–776.
  47. Ion versus Electron Heating in Compressively Driven Astrophysical Gyrokinetic Turbulence. Physical Review X, 10(4):041050.
  48. Dissipation and heating in solar wind turbulence: from the macro to the micro and back again. RSPTA, 373(2041):20140155–20140155.
  49. Astrophysical gyrokinetics: turbulence in pressure-anisotropic plasmas at ion scales and beyond. \jpp, 84(2):715840201.
  50. Instability of the parallel electromagnetic modes in Kappa distributed plasmas - II. Electromagnetic ion-cyclotron modes. MNRAS, 437(1):641–648.
  51. Lele, S. K. (1992). Compact Finite Difference Schemes with Spectral-like Resolution. J. Chem. Phys., 103:16–42.
  52. Collisionless reconnection in magnetohydrodynamic and kinetic turbulence. ApJ, 850(2):182.
  53. Mallet, A. (2020). The onset of electron-only reconnection. Journal of Plasma Physics, 86(3):905860301.
  54. Disruption of Alfvénic turbulence by magnetic reconnection in a collisionless plasma. JPlPh, 83(6):905830609.
  55. MMS Observations of Beta-dependent Constraints on Ion Temperature Anisotropy in Earth’s Magnetosheath. ApJ, 866(1):25.
  56. Instability-driven Limits on Helium Temperature Anisotropy in the Solar Wind: Observations and Linear Vlasov Analysis. ApJ, 748(2):137.
  57. Evolution of the solar wind proton temperature anisotropy from 0.3 to 2.5 AU. Geophys. Res. Lett., 34(20):L20105.
  58. Electron inertia effects in 3D hybrid-kinetic collisionless plasma turbulence. Physics of Plasmas, 30(9):092302.
  59. Can Hall Magnetohydrodynamics Explain Plasma Turbulence at Sub-ion Scales? ApJ, 870:52.
  60. Electron magnetic reconnection without ion coupling in Earth’s turbulent magnetosheath. Nature, 557:202–206.
  61. Properties of Turbulence in the Reconnection Exhaust: Numerical Simulations Compared with Observations. ApJ, 841(1):60.
  62. Onset of fast magnetic reconnection and particle energization in laboratory and space plasmas. Journal of Plasma Physics, 86(6):535860601.
  63. Turbulence and Particle Heating in Advection-dominated Accretion Flows. ApJ, 520:248–255.
  64. Numerical Study of Inertial Kinetic-Alfvén Turbulence. ApJ, 870(2):103.
  65. Evidence of a Cascade and Dissipation of Solar-Wind Turbulence at the Electron Gyroscale. Phys. Rev. Lett., 102(23):231102.
  66. Magnetohydrodynamic and kinetic scale turbulence in the near-Earth space plasmas: a (short) biased review. RvMPP, 4(1):4.
  67. Turbulence, magnetic fields, and plasma physics in clusters of galaxies. Physics of Plasma, 13(5):056501–056501.
  68. Transition from ion-coupled to electron-only reconnection: Basic physics and implications for plasma turbulence. Physics of Plasmas, 26(8):082307.
  69. High-frequency heating of the solar wind triggered by low-frequency turbulence. Nature Astronomy.
  70. Turbulence-driven magnetic reconnection and the magnetic correlation length: Observations from Magnetospheric Multiscale in Earth’s magnetosheath. Physics of Plasmas, 29(1):012302.
  71. Properties of the turbulence associated with electron-only magnetic reconnection in earth’s magnetosheath. The Astrophysical Journal Letters, 877(2):L37.
  72. Properties of the Turbulence Associated with Electron-only Magnetic Reconnection in Earth’s Magnetosheath. ApJ, 877(2):L37.
  73. Multiscale Nature of the Dissipation Range in Gyrokinetic Simulations of Alfvénic Turbulence. PhRvL, 115(2):025003.
  74. A hybrid-Vlasov model based on the current advance method for the simulation of collisionless magnetized plasma. J. Chem. Phys., 225:753–770.
  75. Electron-only Reconnection in Kinetic-Alfvén Turbulence. ApJ, 893(1):L10.
  76. Electron-scale current sheets and energy dissipation in 3D kinetic-scale plasma turbulence with low electron beta. MNRAS, 524(1):1343–1351.
  77. Physical implication of two types of reconnection electron diffusion regions with and without ion-coupling in the magnetotail current sheet. Geophysical Research Letters, 47(21):e2020GL088761. e2020GL088761 2020GL088761.
  78. Winske, D. (1985). Hybrid simulation codes with application to shocks and upstream waves. Space Sci. Rev., 42:53–66.
  79. Magnetic Reconnection in Astrophysical and Laboratory Plasmas. ARA&A, 47(1):291–332.
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