1 / 19

CIRs: Acceleration and transport to high latitudes

2006 Shine Workshop, Zermatt Utah, August 2006. CIRs: Acceleration and transport to high latitudes. J ó zsef K óta & Joe Giacalone w/ thanks to J.R. Jokipii The University of Arizona, Tucson, AZ 85721-0092. kota@lpl.arizona.edu. - Outline -.

bracha
Download Presentation

CIRs: Acceleration and transport to high latitudes

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. 2006 Shine Workshop, Zermatt Utah, August 2006 CIRs: Acceleration and transport to high latitudes József Kóta & Joe Giacalone w/ thanks to J.R. Jokipii The University of Arizona, Tucson, AZ 85721-0092 kota@lpl.arizona.edu

  2. - Outline - • CIR accelerated particles appear as recurrent low-energy events • 1st polar pass of Ulysses: CIR events at high latitudes, where no similar variation in Vsw and/or B present. • Simulations for GCR and low energies • Energy loss and modulation for low-energy particles • Illustrative examples • Compressive acceleration • Summary/Conclusions

  3. Ulysses observations • Recurrent variations in V & B • Corresponding dips in GCR • Enhancements at low energies – continue to be present to highest latitudes

  4. Transport to high latitudes

  5. Interpretation • Fisk field • Cross-field transport (Kóta & Jokipii, 1995,1999). - Parker’s equation - accelerated population wherever divV<0 - cross-field transport κ┴/κ║≈ 0.02-0.05 + Also explains why electrons lag behind ion events

  6. Recurrent particle events at high latitudes: Simulation Low-energy ion/electrons Note delay for electrons Simulated Vsw, B, & GCR fluxes

  7. electrons ions

  8. Cooling along spiral field • Charged particles lose energy even if they move along the spiral field. • Reason curvature drift. More effective at tight spiral (no loss for radial B) dp/dt ~ p Δlnp ~ t VxB field Curvature drift against VxB electric field

  9. Cooling: Numerical Examples • Parker spiral field at latitude 30o • Input: power law spectrum at 15 AU • Fokker-Planck equation for focused transport - Scatterfree: Dμ = 0 - Hemispherical (λ=inf.) - Diffusive: Dμ= w*(1-μ2)/2λ

  10. Field-aligned Transport Skilling (1970), Ruffolo 1995), Isenberg (1997) Kóta & Jokipii (1997): Fokker-Planck equation: Coefficients: Net compression divided into parallel and perpendicular components parallel perpendicular inertial d/dt(ln B) Frozen in !!! d/dt (ln n/B)

  11. Math • Transport coefficients for corotating field: Conservation

  12. `Modulation’ for scatterfree propagation Scatterfree (Dμ=0, λ=inf.) Hemispherical (λ=inf.) Dashed: input at 15AU 15 AU 10 AU 5 AU 1 AU Note discontinuity at 15 AU

  13. Scattering included Fluxes at different radial distances 1AU fluxes for different λ-s λ(AU) = 1.5, 3.5, 7.5, inf. 1, 5, 10, 15 AU

  14. Compressive acceleration • Mason et al (2002) observed energetic particles that must had been accelerated at < 1 AU where shock had not yet been formed • Giacalone et al (2002) interpreted this in terms of compressive diffusion acceleration. Acceleration occurs wherever plasma is compressed (dn/dt > 0). It can be effective if VΔx/κxx < 1

  15. Summary -- CIRs • CIR accelerated particles can reach high latitudes via cross field diffusion • Particles lose energy while moving along (curved) field lines even in scatterfree case • Compression acceleration may occur before shock is formed Zermatt/Matterhorn

More Related