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High Energy Astrophysics Jim Ryan University of New Hampshire.

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Presentation on theme: "High Energy Astrophysics Jim Ryan University of New Hampshire."— Presentation transcript:

1 High Energy Astrophysics Jim Ryan University of New Hampshire

2 High Energy Solar Physics We can use the Sun as a case study of cosmic rays and particle acceleration. After all it is a star. Log 10 E (eV) 5 20 15 Extragalactic Galactic Terrestrial 10 Solar

3 The Earth System ~10 keV, upward E Seen in x rays disrupted upward currents induce resistance (IR drop)

4 Terrestrial Gamma Flashes ~ ms duration, few hundred keV Associated with sprites

5 We see the electromagnetic signature of CR The 100 MeV full sky picture

6 Gamma-ray moon

7 Galactic CR TeV  ray image of SNR Particles being accelerated at interstellar shock Can achieve ~10 15 eV RXJ1713-3946 H.E.S.S

8 Pulsars Acceleration to ~10 13 eV via inductive E field, maybe higher with shocks.

9 Maybe Blackholes Your basic galactic BH Variable high-energy spectrum Reconnection in accretion disk? McConnell et al. 02

10 Extragalactic CR As high as 10 20 eV r g > Milky Way

11 Cen-A Nearest AGN Large structures and strong high speed shocks Chandra VLA

12 Gamma Ray Bursts Lightcurve of SN Cosmological Distances With high Lorentz (  ) factor jets

13 Heliospheric Acceleration Termination shock crossed by Voyager, but no increase in CRs! There are things we do not understand.

14 Now for the Sun 1)Close to home 2)Produces bona fide CRs 3)Can see their effect on the Sun 4)Can detect them directly on Earth 5)Just can ’ t go there, although we can see what is happening.

15 It is difficult to hide the activity

16 We can see what is going on. You can’t do this with AGNs. Ultraviolet structure (TRACE) Optical

17 Model for trapping and acceleration Impulsively inject a monoenergetic particle distribution. Follow coupled space-momentum (acceleration) diffusion. Compute  f at both ends.

18 Protons: –We have plenty of information, perhaps too much. Narrow nuclear lines Broad nuclear lines Neutrons at 1 AU Positron emitters Pions Deuterium formation line Bremsstrahlung from the decay of charged pions Proton capture lines Broadened  -  line High FIP lines and Low FIP lines

19 If we measure the  rays produced what do we end up with?

20 High-E Reaction Channels However,  rays do not give the full picture.  They collapse the projectile identity and energy into a single monochromatic emission.  They also provide only a limited coverage of the ion spectrum. 12 C(p,p’) 12 C* 16 O(p;p’,  ) 12 C* 4.443 MeV 

21 Prolonged  -ray Emission Steady >100 MeV (pion decay) emission, hours after impulsive phase Other examples: –June 1, 4, 6, 9, 15 (all from same region) 100 MeV Sun on 1991 June 11 (Kanbach, priv. comm.)

22 4 November 2003 An even harder spectrum of E – 4 measured later with 10 27 ergs in neutrons (>30 MeV),implying 10 30 ergs in protons with E – 5 spectrum. These energies approach the total energy for many smaller flares. Watanabe et al. SH1.1

23 Are these truly neutrons or protons? Both produce neutrons at ground level Detectable ‘ neutron ’ flares Watanabe et al. SH1.1 Flares with bona fide ground level proton signal. Gopalswamy et al. SH1.4

24 Proton Spectra Typical Broken power law ‘ Saturation ’ spectrum at low energy Ions possess 1 – 15% of the CME and its shock that produced the event, with ~70% of energy in protons. (Mewaldt et al. SH1.3) Mewaldt et al. SH1.2

25 2005 January 20 Ratio between MW and Durham indicates p –6.5 spectrum. Rise time and initial decay in both Climax and Milagro are identical.

26 Very rapid CME. Speed estimate of 3500 km-s – 1. Necessary to produce accelerating shock close to Sun. Gopalswamy et al. 2005

27 Where was the 5 GV proton acceleration and release? CME (SXI loops) liftoff time 0633 UT Solar Wind Speed~560 km-s – 1 Pitch angle cone half angle  20˚ Milagro GLE onset 0651.2 UT CME speed 3500 km-s – 1  ~2.3-2.7 R s (Farrugia, priv. comm.) (Gopalswamy et al. 05)

28 So, what do we learn? We can study processes that produce serious cosmic rays. We are close enough to constrain and model these processes based on what we see. (Solar theory is not for wimps.) We always see new things that stimulate new thinking—that’s why we do this.

29 So, what do we need in future?  ray measurements: good E resolution from 0.2 to 100 MeV and a diagonal response, Imaging like RHESSI Neutrons: At 1 AU 15 to 200 MeV spectroscopy At <0.5 AU 1 to 15 MeV spectroscopy

30 New Windows The neutron Sun “ Thou comst in such a questionable shape. ” (Hamlet)

31 Resolving the spectrum/composition problem with neutrons Need additional diagnostics and measures to constrain the combinations of spectrum and composition. and neutrons at all energies. The answer may be in measuring gammas and neutrons — neutrons at all energies. Would provide new sensitivity above 50 MeV and independent measure of ‘heavy’ constituent.

32 SHOCK CME FLARE x and  rays NEUTRONS PARKER SPIRAL MAGNETIC FIELD HIGH ENERGY PARTICLES 35-40 R 0 5-15 R 0 PASO SUN

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