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Diffusive Shock Acceleration
Nepomuk Otte MAGIC/EUSO Seminar
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Outline About Trucks and Tennis Balls Second Order Fermi
First Order Fermi Energy spectrum Maximum Energies
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About Trucks and Tennis Balls
mass M=40t velocity vtruck = 80km/h on German Highways (sometimes 110 km/h)
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About Trucks and Tennis Balls
mass m = 56,7…58,7 g velocity vball = 200 km/h
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About Trucks and Tennis Balls
vtruck vball what happens in a head on collision? M>>m and vball>>vtruck
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About Trucks and Tennis Balls
vtruck vball negligible relative change in momentum and energy of truck But the tennis ball: momentum |p| and kinetic energy W is increasing due to energy transfer from the truck onto the ball ΔE/E ≈ 4 vtruck/vball Acceleration of the ball
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Diffusive Shock Acceleration
Light particles gain energy in head-on elastic collisions on heavy slower moving objects The same mechanism also works in the universe: at much longer timescales with much smaller efficiency
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Fermi Acceleration I follow:
Origin and Propagation of the highest energy cosmic rays R. J. Protheroe astro-ph/ Cosmic Rays and Particle Physics T. K. Gaisser chapter 11 High Energy Astrophysics: Volume 2 M. S. Longair chapter 21 The acceleration of cosmic rays in shock fronts I R. Bell MNRAS (1978) 182, The acceleration of cosmic rays in shock fronts II A. R. Bell MNRAS (1978) 182,
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The Original one: 2nd Order Fermi Acceleration or Elastic scattering of cosmic rays in magnetized clouds Inputs: relativistic isotropic particle distribution heavy, magnetized, non relativistic gas cloud with velocity v b
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2nd Order Fermi Acceleration
due to cloud movement head on collisions are slightly more probable particle is randomly scattered on the magnetic field in the cloud (diffusion process)
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2nd Order Fermi Acceleration
Transforming into rest frame of cloud: Particle is scattered into No change of particle Energy in the cloud system Energy change in the lab frame
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2nd Order Fermi Acceleration
Second order because of and particle can win and loose energy in a single encounter very small gain in energy after many encounters
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The More Efficient Version 1st Order Fermi
planar shock front instead of gas clouds
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1st Order Fermi Acceleration
In SN ejected material propagates with VP~104 km/s >> speed of sound (~10 km/s) Shock wave with speed Vs= 4/3 Vp particles crossing the shock front generate Alfvén waves Alfvén waves are low frequency hydromagnetic plasma oscillation chaotic distribution of magnetic fields
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1st Order Fermi Acceleration
Average for a particle entering the shock same scenario when the shock has bee crossed the plasma on the other shock side is approaching with velocity Vp Average energy gain for a full cycle
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1st Order Fermi Acceleration
Is first order in b More efficient always gain in energy
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Probability for one Shock Crossing
Net flow of particles in downstream direction Rate at which particles are lost from the shock in downstream:
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Probability for one Shock Crossing
Net flow of particles in downstream direction Rate at which particles cross the shock from upstream to downstream: assume isotropic particle distribution upstream and particle speed
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Probability for one Shock Crossing
Probability Pe for crossing the shock once and then escaping it: assuming: Probability Pr for crossing the shock once and returning to it:
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Energy Spectrum Probability to cross the shock at least k times
Number of particles N with energy ≥ E Eliminate k Integral spectrum
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Shock Acceleration Rate
need tcycle
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Shock Acceleration Rate
time spent downstream: particles move with velocity u2 in the downstream region away from shock In addition diffusion adds to this movement define border beyond which particle escapes the shock t=4/c*k/u
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Shock Acceleration Rate
analogue to downstream works also for the upstream region Several possibilities for the diffusion constant lower limit given by with
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Maximum Energies Acceleration is limited by synchrotron radiation
maximum Energy for Electrons duration of shock ~1000yrs pion production Bethe Heitler pair production finite acceleration size
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Summary Fermi acceleration is elastic scattering on magnetic fields
Energy gain per cycle in second order Fermi in first order Fermi 1st order produces E-2 differential spectrum Maximum energy ≈ 100 TeV/nucleon
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