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Foreshock and planetary size: A Venus-Mars comparison M. Yamauchi, Y. Futaana, R. Lundin, S. Barabash, M. Holmstrom (IRF, Kiruna, Sweden) A. Fedorov, J.-A.

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Presentation on theme: "Foreshock and planetary size: A Venus-Mars comparison M. Yamauchi, Y. Futaana, R. Lundin, S. Barabash, M. Holmstrom (IRF, Kiruna, Sweden) A. Fedorov, J.-A."— Presentation transcript:

1 Foreshock and planetary size: A Venus-Mars comparison M. Yamauchi, Y. Futaana, R. Lundin, S. Barabash, M. Holmstrom (IRF, Kiruna, Sweden) A. Fedorov, J.-A. Sauvaud, C. Mazelle (CESR, Toulouse, France) R.A. Frahm, J.D. Winningham (SwRI, San Antonio, USA) E. Dubinin, M. Fraenz (MPS, Katlenburg-Lindau, Germany) T.L. Zhang, W. Baumjohann (IWF, Graz, Austria) A.J. Coates (UCL/MSSL, Surrey, UK)

2 FAB: field-aligned beam FAB + FS: foreshock 1. Introduction: Earth's knowledge 2. Venus (similar to Earth) 3. Mars (Different from Venus/Earth) Outline

3 // beam ~ |V sw |

4 Venus (VEX) connected to BS

5 SW 1. Field- aligned H +. 2. Gyrating H + with large V //.  Same as the Earth

6 cf. Earth V  1 - V // (projection at V  2 =0) V  1 - V  2 (cut at V // =-1000 km/s) Venus foreshock ≈ Earth foreshock How about Mars?

7 (1) only "ring" distribution (2) no "foreshock" signature (examined ~ 500 traversals) BS Quite different from Venus:

8 (1) Alfvén Mach number (M A ) x  (2) Gyroradius (r g ) / Bow-shock radius (R S ) (3) Inertia length (c/  pi ) / Bow-shock size (R S ) SW parameter R S (BS radius) M A (  n 1/2 V/B) c/  pi (  n -1/2 ) & c/  pi R S r g (  V/B) & r g /R S Venus 1 1 1 & 1 Mars~ 0.5~ 1.4~ 3 & ~ 5~ 4 & ~ 8 For Mars: R S ~ 5000 km for Martian Subsolar 2 keV H + under 6 nT  r g = 1000 km 5/cm 3 H +  c/  pi = 100 km Venus-Mars difference: (1) parameters

9 1. solar wind, 2&3. bow-shock cold ion, 4. sneak out ∆V // << V // (yes), ∆V // << V // (yes), ∆V // ~ V // (no), ∆∆ ∆∆ Due to the finite curvature, some ions do not re-enter

10 Venus-Mars difference: (2) cold H+ (1) Gravity: Venus > Mars  (2) Exosphere: Venus < Mars  (3) newly born H+: Venus << Mars (This is clear from the difference in “ring distribution”)  (4) cold H+ at Bow shock: Venus << Mars (High density cold H+ is observed only for Mars)

11 (1) Alfvén Mach number (M A ) (2) Gyroradius (r g ) / Bow-shock radius (R S ) (3) Inertia length (c/  pi ) / Bow-shock size (R S ) (4) Cold ion inside Bow-shock parameterRSRS MAMA c/  pi R S r g /R S cold H+ at BS Venus 1 1 1 1very little Mars~ 0.5~ 1.4~ 5~ 8a lot Venus - Mars difference (summary) ?? ??

12 Examine close to the Bow Shock MEX We sometimes observed “multiple-ring” structure. c/  pi rgrg

13 beyond c/  pi within r g = reflected ions Three types of accelerated ions within c/  pi = foot ions beyond r g = pickup ions  obtain B direction

14 3rd // acc 2nd // acc main // acc pre-acc heating

15 green: foot blue: primary ring red: 1st branch purple: 2nd branch brown: 3rd branch Multiple acceleration Gyro-phase bunching red: half gyro purple: one third gyro

16  within BS escape (Since V dHT > |V SW |, dHT frame is erroneous)

17 SW Reflection  convert V  to V // in SW frame ∆∆ The observed multiple ring structure is well explained by multiple specular reflection. But, why is it observed outside the foot region?  no : Finite bow shock size compared to r g. yes: Cold ion in the bow shock  This may explain “non-specular reflection” at subsolar.

18 Special features for Mars Energy is stepping (due to reflection?) Gyro-bunching effect (due to short distance?) with gradual  acceleration (why?) Two different scale length No specular reflection near the bow shock (need to confirm)

19 Venus ≈ Earth No internal magnetic field. Planet is the same size as the Earth  Smaller bow shock size than the Earth, yet MHD regime. Effect of cod ions in the bow shock can be ignored. No internal magnetic field. Planet is smaller than the Earth.  The bow shock size is too small to treat with MHD. Effect of cod ions in the bow shock cannot be ignored. Mars  Earth

20 (1) Alfvén Mach number (M A ) (2) Gyroradius (r g ) / Bow-shock radius (R S ) (3) Inertia length (c/  pi ) / Bow-shock size (R S ) (4) Cold ion inside Bow-shock parameterRSRS MAMA c/  pi R S r g /R S cold H+ at BS Earth 5~ 1.2~ 0.3~ 0.4no Venus 1 1 1 1very little Mars~ 0.5~ 1.4~ 5~ 8a lot Ending (add Earth) ?? ??

21 End

22

23 IMA looking direction VEX

24

25 Multiple-Reflection S E S: toward BS from left S&E: toward BS from left S ~ V HT = along BS E: along BS S: along BS E: toward BS E: toward BS from right x x (0.6, -0.8, 0) XYZ

26 3rd // acc 2nd // acc main // acc pre-acc heating Time = Spatial variation

27 B (N-direction) is estimated from minimum variance method applied to the ring distribution Classifying counts in // and  directions Time = Spatial variation

28 Three configurations (on-going work) 2005-7-29 2005-8-3 2005-7-12 2005-8-5 Done

29 Summary Venus Express / ASPERA-4 often observes back- streaming H + in the foreshock region of Venus, in a similar ways as the Terrestrial foreshock, i.e., field- aligned component, and intermediate (gyrating) component Mars Express / ASPERA-3 (same instrumentation as VEX) did not observe similar ions in the Martian foreshock region beyond the foot region. Instead, it shows different type of acceleration in the foot region, indicating the ion trajectory (history) during its gyromotion. The finite gyroradius effect makes Mars a perfect laboratory to study acceleration processes.

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