1 / 30

Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves

Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves. Richard B. Horne 1 R. M. Thorne 2 , S. A. Glauert 1 , N. P. Meredith 1 D. Poktelov 3 , and O. Santolik 4 1. British Antarctic Survey 2. University of California, Los Angeles 3. University of Bath

quinta
Download Presentation

Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves Richard B. Horne1 R. M. Thorne2, S. A. Glauert1, N. P. Meredith1 D. Poktelov3, and O. Santolik4 1. British Antarctic Survey 2. University of California, Los Angeles 3. University of Bath 4. Charles University, Prague R.Horne@bas.ac.uk REPW, Rarotonga, 7 August, 2007

  2. [Baker and Kenekal, 2007] The Problem • Solar wind velocity related to electron flux variations inside the Van Allen radiation belts • Flux variations are due to acceleration, transport and loss inside the magnetosphere • How do you produce >1 MeV electrons from a source of ~ keV electrons?

  3. Magnetosonic Waves • Magnetosonic waves propagate across Bo, fcH < f < fLHR • Intense • Generated by proton ring distributions [e.g., Boardsen et al. 1992]

  4. Fast compressional magnetosonic wave B field and plasma compressions Bw is along Bo, and Ew is perpendicular to Bo and k Low Frequency Propagation Perpendicular to B

  5. Latitude Distribution of MS Waves from CLUSTER Nemec et al. PSS [2005]

  6. Ion ring distributions form during magnetic storms Energy dependent drift Slow drift - loss Injection into existing population Boundary between open and closed drift paths Ion Ring Distributions Fok et al. JGR, [1996]

  7. Weak Storm Event

  8. Solve with dispersion relation Not field-aligned ! Cyclotron resonance >3 MeV unlikely to contribute Landau resonance possible Energy diffusion Higher energies at larger pitch angles For a band of waves with spread of directions Landau resonance extended over pitch angles Resonant Diffusion

  9. Band of waves – Quasi-linear diffusion approach Diffusion coefficients – use PADIE code [Glauert and Horne, 2005] estimate acceleration and loss timescales Least squares fit to CLUSTER data Gaussian distribution of power Propagation at 89o with angular spread Landau and 5 cyclotron resonances Bounce average over 3o latitude Fit to CLUSTER Data

  10. Angular Power Spectral Density • Wave normal angle distribution is confined to large angles to be consistent with propagation within +- 3-5 degrees latitude

  11. Diffusion Rates Outside plasmapause Inside plasmapause

  12. Magnetosonic waves, L=4.5 x0.6 for bounce and drift average Chorus, L=4.5, Bounce and drift averaged Chorus – MSonic Comparison Horne et al., JGR [2005]

  13. Magnetosonic waves do not cause loss by precipitation, but accelerate electrons inside the magnetic field Acceleration possible from ~ 30 keV to a few MeV Occurrence rate is ~ 60% between 3.9 and 5 Re [Santolik et al., 2004] Assuming present for 60% of the drift orbit Diffusion rates are comparable to those for whistler mode chorus Needs a full wave survey!! Suggest they contributed to acceleration during 25 Nov 2002 Since the waves are generated by protons, and acceleration electrons Energy transfer from ring current to radiation belts Conclusions

  14. CRRES Initial Survey of MSonic Waves • Outside plasmapause only – Substorm related phenomena

  15. Fine Structure

  16. Frequency Distribution of MS Waves from CLUSTER Nemec et al. PSS [2005]

  17. Growth of Magnetosonic Waves

  18. L=4.95 Ring peaks at 25 keV and 10 keV Data from Gloeckler et al. [1985] Model, from observed electron distribution Magnetosonic Wave Generation Protons Electrons

  19. Growth Rates • Growth peaked near harmonics of fcH • Plasmasheet electrons restricts growth • Landau damping Horne et al., JGR [2000]

  20. Propagation and Growth • Confined to equatorial region by Landau damping • electron acceleration • Propagate across plasmapause • Can also propagate around in MLT • Guided by plasmapause Horne et al., JGR [2000]

  21. Msonic waves also diffuse ions Ion heating near 90 degrees 10-100 keV Tries to remove the ring distribution Does this help excite EMIC waves? Ion Diffusion

  22. Summary • Magnetosonic waves may be as effective as chorus for electron acceleration • Propagate at large angles to Bo • Cannot use Danny’s approximation to calculate diffusion rates • Appear to be substorm related • Generated by ion ring distributions • Substorm ion injection provides the seed population • Transfer energy from Ring current to radiation belt • But no simple relation between ring current and radiation belt • Cause ion diffusion and heating • Does this help excite EMIC waves? – See Vania • Need to survey the wave power in MLT to determine effectiveness

  23. The End

  24. Ion Cyclotron Absorption • Inward radial propagation from L=6.5 • Cyclotron resonant absorption by protons • Absorption increases with proton temperature • N=18 resonance shown as an example • Waves diffuse and heat ions

  25. Dispersion, Multi-ion Plasma

More Related