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Generation of the transpolar potential

Generation of the transpolar potential. Ramon E. Lopez Dept. of Physics UT Arlington. How does the solar wind drive convection?. Dungey [1961] Reconnection Most of the potential - up to hundreds of kV. Axford and Hines (1961) Viscous interaction ~20-30 kV.

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Generation of the transpolar potential

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  1. Generation of the transpolar potential Ramon E. Lopez Dept. of Physics UT Arlington

  2. How does the solar wind drive convection? Dungey [1961] Reconnection Most of the potential - up to hundreds of kV Axford and Hines (1961) Viscous interaction ~20-30 kV

  3. Linear reconnection driving by the solar windso

  4. Transpolar Potential Saturation (storm main phases) See also Ober et al., (2003), Hairston et al. (2003)

  5. Linear regime - Geoeffective length • The solar wind voltage across the 32 Re Y-extent of the dayside magnetopause is 204 KV for every mV/m in the solar wind • So the actual projection of the solar wind voltage onto the X-line (which extends from terminator to terminator) must be less • From previous figure we get TP = 46*VBz + 15Solar wind projection is 7.2 Re in Y-extent • What does the LFM do?

  6. LFM MHD Simulation Potential

  7. Viscous Potential increases with Solar Wind speed

  8. The Potential has 2 parts (for now) Viscous Potential - Φv(V, n, Σp) We determine this for each parameter set of runs, then subtract it from the total potential Reconnection Potential - Φr(V, n, Σp, B) The potential along the merging line is the rate at which flux crosses the merging line.

  9. LFM MHD Simulation Potential

  10. The geoeffective length is directly confirmed by following plasma flow streamlines from the solar windSee also Merkin et al. (2005)

  11. What controls the projection of the solar wind on the X-line? • The flow is determined by the total forces acting in the magnetosheath. • When B in the solar wind gets large, the nature of the force balance changes from a plasma pressure-dominated flow to a magnetic stress-dominated flow. • I argue that this transition is what controls the transition to the saturation of the transpolar potential

  12. Y-extent of streamlines intersecting X-line shrinks for beta<1

  13. Geoeffective lengths give Reconnection Potential

  14. n = 8/cc, Bz = -10 nT Density dependence • Higher density needs higher Bz to transition to beta<1 in sheath, hence larger potentials in the saturation regime n = 5/cc, Bz = -10 nT

  15. Σ = 5 mho, Bz = -10 nT Conductivity dependence • Higher ionospheric conductivity results in greater magnetopause erosion, a thicker magnetosheath, lower beta in the sheath, more diversion of the flow, hence smaller a saturation potential Σ = 10 mho, Bz = -10 nT

  16. Velocity dependence Solar Wind Speed Viscous Potential Geoeffective Length • Higher solar wind speed produces a larger pressure force in the magnetosheath • This reduces the geoeffective length in the solar wind Sound Speed dependence as well!

  17. LFM shows expected behaviors

  18. How does this agree/differ with the Siscoe-Hill model?

  19. What are these potentials? Φm given by solar wind electric field times the geoeffective length Φs given by the value of the Region 1 current that weakens the dayside field by about 50% Region 1 takes over from the Chapman-Ferraro current and exerts force balance with the solar wind

  20. The bow shock current

  21. Where does the current go?

  22. Look at the direction of the current in the volume at Z=0 Bz = -20 nT V = 400 km/s n = 5 Cs = 40 km/s

  23. The magnetic force can be the largest force in the magnetosheath if beta<1

  24. Now we can understand the dependence on the geoeffective length on beta and solar wind V The larger the divergence of the flow, the smaller the geoeffective length. Larger plasma pressure causes a greater divergence When JxB takes over, a larger B causes a greater divergence

  25. What about closure of the bow shock current through the ionosphere?

  26. Thesecurrents exist!Lopez et al., 2008JASTP

  27. Vx= 400km/s, Vz = -150 km/s, Bz= -15 nT Density Jy More current flows to the north! φnorth > φsouth with Σpconstant. This cannot be due to reconnection!

  28. Driving via the Bow Shock Generator The current in the bow shock is a generator This dynamo current acts as a source for potential Bz = -20 nT, V = 400 km/s, n = 5/cc Current streamlines Density color-coded

  29. Interhemispheric asymmetry and the Convection Reversal Boundary location for large southward IMF • Summer hemisphere has higher FAC, lower potential relative to winter hemisphere • Convection reversal boundary in both hemispheres located in open field line region - not at the boundary between open and closed field lines • This is necessary since the reconnection potential must be the same in both hemispheres

  30. Halloween storm observations are consistent

  31. Aug 10,2000 0 nT 0 nT -13.5 nT nT Text Text

  32. Good northern hemisphere passClear convection pattern

  33. Upward FAC 66.5˚ 66.8˚

  34. Closed 2-cell convection in the polar cap driven by closure of bow shock current DMSP F13 path Polar cap

  35. Let’s not restrict ourselves to Bz<0 Wilder et al. (2007, 2009) have shown saturation for northward IMF in SuperDarn observations LFM saturates for large northward IMF DMSP data do the same thing

  36. What about large By? LFM exhibits saturation

  37. AIME and DMSP confirm it VBy = 8 mV/m Well within saturation

  38. Sample DMSP Observations VBy = 8.1 mV/m ΦF13 = 99.2 kV F13 ΦF15 = 100.5 kV F15

  39. 5 mho β-dependent saturation onset 20 mho

  40. Reconsider the Siscoe-Hill model The value of the saturation potential is lower for east-west IMF (and lower still for northward IMF) Therefore Region 1 currents are lower for a By-saturated potential compare to a Bz-saturated one Neither force balance nor dayside Region 1 magnetic perturbation control the onset of saturation. However, the transition to a magnetically-dominated magnetosheath does.

  41. What about closure of the bow shock current for large By?

  42. January 10, 1997 CME-driven storm OMNI data:Bx = -5.5 nTBy = -13.2 nTBz = -2.1 nT

  43. Precipitating electrons - the upward current in the polar cap?

  44. Convection reversal coincident with the precipitation!

  45. Lobe cell convection • Birkeland Current driven by bow shock will drive convection • All on open field lines • Lobe cell convection may not be reconnection driven

  46. Bow shock dynamo and coupling to geospace • The solar wind flow energy dissipated at the bow shock creates a dynamo (J•E<0). This in part powers dayside merging (Siebert and Siscoe, 2002). • The bow shock current closes in part through the ionospheric load (J•E>0) where it can impose a potential in the polar cap and dissipate solar wind mechanical energy extracted at the shock • This represents a means of driving ionospheric and magnetospheric convection without reconnection or viscous interaction at the magnetopause - it is a third fundamental mode of driving convection!

  47. Conclusions • The behavior of the reconnection part of the transpolar potential can be understood in terms of basic physics (Faraday’s Law, MHD momentum equation) • The divergence of the magnetosheath flow explains the magnitude of the linear potential, the transition to the saturated potential, and dependencies on solar wind • The closure of the bow shock current in the ionospheric polar cap is distinct from both reconnection and the viscous interaction. It is a fundamental mechanism by which solar wind mechanical energy extracted at the shock is deposited in the geospace system. • Thus there are three sources of ionsopheric potential: reconnection, viscous interaction, and bow shock current closure

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