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Shock Acceleration of Thermal and Hot Seed Ion Populations Martin A. Lee University of New Hampshire September 16-17, 2008.

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Presentation on theme: "Shock Acceleration of Thermal and Hot Seed Ion Populations Martin A. Lee University of New Hampshire September 16-17, 2008."— Presentation transcript:

1 Shock Acceleration of Thermal and Hot Seed Ion Populations Martin A. Lee University of New Hampshire Marty.Lee@unh.edu September 16-17, 2008

2 Building a Foreshock Database We have been engaged in building a database of field and particle observations upstream and downstream of shocks. –Have employed 8 undergraduate students. Resulting in 1 finished Senior Thesis (David Sodaitis) and second underway (Michael Winder). –Have examined 66 shocks so far. –Provided material for IGPP Hawaii conference talk and paper plus 2 AGU posters plus 2 SHINE posters.

3 Preparing Shock Paper(s) We met Mihir and Maher 2 days in July to refine shock choices. –Selected 17 shocks for study using ACE/WIND data. –Will produce 2 papers using proton, composition, and IMF analyses. Senior Mike Winder is serving as numerical analyst (and learning a lot!). –Mike will do his Senior Thesis with us. We are working on those papers now.

4 Example Event: 1999 / 47-49 (Cold Seeds) Density compression:  d /  u ~ 2.9  0.1 and  Bn = 50  2. Clear proton foreshock of appropriate scale. Softening particle spectra on the same ESP scale. Particle intensity index appropriate to shock strength. Small proton anisotropy. Wave foreshock appropriate scale. Argued and confirmed to be cold ion seed population leading to shock acceleration.

5 EPAM Spectra (Cold Seeds) Weak spectra (either very soft or low in intensity) will behave as cold seed ions and accelerate to the form predicted by the shock strength. Higher energies escape before steady-state form is achieved.

6 Example Event: 1998 / 217-219 (Hot Seeds) Density compression:  d /  u ~ 1.8  0.1 and  Bn = 82  3. Very modest or questionable proton foreshock if SEP event is properly recognized. Softening particle spectra on SEP scale. Moderate proton anisotropy. Nonexistent wave foreshock. Argued and confirmed to be hot ion seed population leading to shock acceleration.

7 EPAM Spectra (Hot Seeds) Hot source ions rise in intensity, but do not adopt asymptotic form dependent on shock strength. Little if any evolution of the spectrum from several hours upstream to immediately behind the shock

8 Planar Stationary SA

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12 Extra Slides

13 Example Event: 1998 / 273-275 (Cold Seeds) Density compression:  d /  u ~ 2.6  0.3 and  Bn = 52  6. Apparent proton foreshock if SEP event is properly recognized (but extensive). Softening particle spectra on realistic scale. Small proton anisotropy. Modest wave foreshock. Argued and confirmed to be cold ion seed population leading to shock acceleration.

14 EPAM Spectra Weak spectra (either very soft or low in intensity) will behave as cold seed ions and accelerate to the form predicted by the shock strength. Higher energies escape before steady-state form is achieved.

15 Example Event: 1999 / 264-266 (Hot Seeds) Density compression:  d /  u ~ 2.4  0.5 and  Bn = 64  7. Questionable proton foreshock if SEP event is properly recognized. Softening particle spectra on SEP scale. Strong proton anisotropy. Questionable wave foreshock. Argued and confirmed to be hot ion seed population leading to shock acceleration.

16 EPAM Spectra (Hot Seeds) Hot source ions rise in intensity, but do not adopt asymptotic form dependent on shock strength. Little if any evolution of the spectrum from several hours upstream to immediately behind the shock

17 Shock Working List Cold Seed Ions Mixed Seed Ions Hot Seed Ions 1998 / 2752002 / 1131998 / 218 1999 / 0492002 / 1381999 / 265 2001 / 2392002 / 2301999 / 294 2004 / 1032000 / 042 2005 / 2582000 / 097 2001 / 169 2001 / 229 2003 / 149 2003 / 150

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