Acceleration of Cosmic Rays

1. Acceleration of Cosmic Rays E.G.Berezhko Yu.G.Shafer Institute of Cosmophysical Research and Aeronomy Yakutsk, Russia • Introduction • General properties of Cosmic Ray (CR) acceleration • Diffusive shock acceleration • Acceleration of CRs in Supernova Remnants (SNRs) • Nonthermal emission of individual SNRs • SNRs as Galactic CR source • Some aspects of UHECR production in GRBs and extragalactic jets • Conclusions

2. Cosmic Rays V.Hess (1912) I ≈ 1 particle/(cm2s) I ~ ε-γ γ≈ 2.7 Earth LCR ≈ 3×1041 erg/s Atmosphere CR origin problem: i) CR source (?) ii) Acceleration mechanism (?)

3. General remarks • Cosmic Rays (CRs) = atomic nuclei = charged particles • Electric field is needed to generate (accelerate) CR population • High value large scale electric field is not expected • in space plasma • Electric field in space plasma is created • due to the movement of magnetized clouds • For efficient CR production (acceleration) the system, • which contains strong magnetic field and sufficient number • of rapidly moving clouds, is needed

4. vi vf vi vf CR scattering on moving magnetized clouds CR vi Head-on collision: Δv = vf – vi >0 E = -[w B]/c w E vf scattering center × B w = 0 v >> w Δv = 0 E Overtaken collision: Δv = vf – vi <0 B w w = 0 w Elastic scattering: vf = vi vf > vi Elastic scattering: Larger rate of head-on then overtaken collisions efficient CR acceleration

5. General remarks • CR acceleration, operated in the regions of powerful sources, • are the most meaningful • The main form of energy available in the space is • kinetic energy of large scale supersonic plasma motion • (stellar winds, expanding supernova remnants, jets) • Most relevant acceleration mechanisms are those, • which directly transform the energy of large scale motion • into the population of high energy particles • Intense formation of CR spectra are expected to take place • at the shocks and in shear flows

6. Solar wind

7. Diffusive shock acceleration of CRs Krymsky 1977 Bell 1978 log NCR p- Δp log p scattering centers  = ( + 2)/( -1) shock compression ratio

8. Frictional Acceleration of Cosmic Rays Berezhko(1981) y Shear plasma flow w CR scattering center acceleration rate mean scattering time x Frictional CR acceleration is expected to be very efficient in relativistic/subrelativistic jets

9. Energetic requirements to CR sources

10. Requirements to the CR acceleration mechanism Jobs~ ε–γobs ~ Js/τesc observed CR spectrum γobs = 2.7 Τesc ~ ε-μ( μ = 0.5 - 0.7) CR residence time inside the Galaxy JS~ε-γS γS = γobs – μ = 2 – 2.2 source CR spectrum

11. Supernova explosions Supernova explosions supply enough energy to replenish GCRs against their escape from the Galaxy If there is acceleration mechanism which convert ~10% of the explosion energy into CRS

12. Cosmic Ray Flux Possible GCR sources: SNRs knee SNRs (?) Reacceleration (?) ankle Extragalactic (?) GZK cutoff (?)

13. Cosmic Ray diffusive acceleration in Supernova Remnants ESN~ 1051erg Krymsky 1977 Bell 1978 shock compression ratio for strong shock

14. Nonlinear kinetic (time-dependent) theory of CR acceleration in SNRs • Gas dynamic equations • CR transport equation • Suprathermal particle injection • Gas heating due to wave dissipation • Time-dependent (amplified) • magnetic field Applied to any individual SNR theory gives at any evolutionary phase t>0 :nuclear Np(p,r), NHe(p,r), … and electron Ne(p,r) momentum and spatial distributions, which in turn can be used for determination of the expected nonthermal emissions Fγ(εγ)

15. Nonlinear kinetic model: basic equations Berezhko, Yelshin, Ksenofontov (1994) ρ(r, t) – gas density w(r, t) – gas velocity Pg(r, t) – gas pressure f (p, r, t) – CR distribution function Hydrodynamicequations CR transport equationsfor protons and electrons (Krymsky, 1964) CR pressure source term CR diffusion coefficient Synchrotron loss time u = Vs - w

16. Particle spectrum in/near acceleration region injection rate (parameter) η > 10-5→ efficient CR production

17. Nonlinear effects due to accelerated CRs • Modification of the shock structure due to CR pressure gradient • Non power law (concave) CR spectrum • Magnetic field amplification (Lucek & Bell, 2000) • Increase of maximum CR energy • Increase of π0-decay gamma-ray emission • over IC emission

18. CR spectrum inside SNR p test particle limit maximum CR momentum due to geometrical factors (Berezhko 1996) ppmax~ RSVSB

19. Main nonthermal emission produced by Cosmic Rays(how one can “see” CR sources) • Synchrotron radiation radio B X-ray e • Inverse Compton scattering  gamma-rays  e  • Nuclear collisions  N gamma-rays p

20. Nonthermal emission of SNRs • Test for CR acceleration theory • Determination of SNR physical parameters: • - CR acceleration efficiency • - Interior magnetic field B

21. Relevant SNR parameters SNR aget known for historical SNRs ISM density NH influences SNR dynamics and gamma-ray production; deduced from thermal X-rays influences CR acceleration & synchrotron losses; deduced from fit of observed synchrotron spectrum; expected to be strongly amplified B >> BISM magnetic fieldB influences accelerated CR number, shock modification, CR spectral shape; deduced from observed shape of radio emission injection rate η (fraction of gas particles, involved in acceleration)

22. CR spectrum inside SNR p e test particle limit radio X-ray due to synchrotron losses Steep radio-synchrotron spectrum Sν ~ν-α (>0.5,  >2) is indirect evidence of i) efficient proton acceleration and ii) high magnetic field B>>10G α = (γ – 1)/2

23. Cassiopeia A Type Ib Distance 3.4 kpc Age 345 yr Radius 2 pc Circumstellar medium: free WR wind + swept up RSG wind + free RSG wind Tuffs(1986), VLA

24. Circumstellar medium MS → RSG → BSG → SN Borkowski et al. (1996) Ng, cm-3 CSM number density current SN shock position 10 shell 1 RSG wind BSG wind 1 r, pc 2 d = 3.4 kpc Mej = 2 MSun ESN = 0.4×1051 erg

25. Berezhko et al. (2003)

26. Synchrotron Emission from Cassiopeia A Experiment: radio (Baars et al. 1977), 1.2 mm data (Mezger et al. 1986), 6 m data (Tuffs et al. 1997), X-ray data (Allen et al. 1997) Proton injection rate η = 3×10--3 Interior magnetic field Bd ≈ 0.5 mG Strong SN shock modification Steep concave spectrum at ν < 1012 Hz Smooth connection with X-ray region (ν > 1018 Hz) α≈ 0.8

27. Magnetic field inside SNRs Emission (X-ray, γ-ray) due to high energy electrons Rs J Low field L ρ ρ Line of sight J High (amplified) field ρ Unique possibility of magnetic field determination! -Rs Rs 0

28. Chandra SN 1006 Chandra Cassiopeia A • Filamentary structure of X-ray emission • of young SNRs • consequence of strongly amplified magnetic field, • leading to strong synchrotron losses

29. Projected X-ray brightness of Cassiopeia A direct evidence for magnetic field amplification Theory:Berezhko & Völk (2004) Experiment (Vink & Laming 2003) confirms high internal magnetic field extracted from the fit of volume Integrated synchrotron flux (Berezhko, Pühlhofer & Völk 2003) Bd = 10 μG Bd = 500 μG For strong losses L emissivity scale brightness scale angular distance

30. Integral gamma-ray energy spectrum of Cas A Components: Hadronic (π0) Inverse Compton (IC) Nonthermal bremsstrahlung (NB) Confirmation of HEGRA measurement is very much needed Already done by Magic (ICRC, Merida 2007)!

31. SNR RX J1713.7-3946 X-rays (nonthermal) ROSAT(Pfeffermann & Aschenbach 1996) ASCA (Koyama et al. 1997; Slane et al. 1999) XMM (Cassam-Chenai et al. 2004; Hiraga et al. 2005) Gamma-ray image (HESS) Aharonian et al. (2005) Radio-emission ATCA (Lazendic et al. 2004) VHE gamma-rays CANGAROO (Muraishi et al. 2000) CANGAROO II (Enomoto et al. 2002) HESS (Aharonian et al. 2005)

32. Spatially integrated spectral energy distribution of RX J1713.7-3946 Experiment: Aharonian et al. (2006) Theory: Berezhko & Völk (2006) required interior magnetic field Bd = 126 μG

33. Magnetic field amplification ρISM Results of modeling (Lucek & Bell, 2000) + Spectral properties of SNR synchrotron emission + Fine structure of nonthermal X-ray emission Beff VS BISM SNR magnetic field is considerably amplified L Beff2/8π ≈ 10-2ρISMVS2 Bd = Beff >> BISM

34. SNR magnetic field • Influences synchrotron emission • Determines CR diffusion mobility: Κ ~ p/(ZBd) CR diffusion coefficient (Bohm limit) • Influences CR maximum momentum pmax: pmax~ Z e Bd RS VS nuclear charge number

35. Energy spectrum of CRs, produced in SNRs Berezhko & Völk (2007) Amplified magnetic field Bd2/(8π) ≈ 10-2ρ0VS2 Bd >> BISM

36. Cosmic Ray Flux CR sources: Supernova remnants knee 1 Supernova remnants knee 2 Extragalactic (?) GZK cutoff (?)

37. Energy spectrum of CRs Dip p + γ→ p + e+ + e- Dip scenario GZK cutoff p + γ→ N + π Experiment: Akeno-AGASA (Takeda et al. 2003) HiRes (Abbasi et al. 2005) Yakutsk (Egorova et al. 2004) CR spectrum, produced in SNRs CR spectrum from JEG~ε-2.7 extragalactic sources (Berezinsky et al.2006)

38. Energy spectrum of CRs Ankle scenario Extragalactic (AGNs, GRBs…) JEG~ε-2 Berezinsky et al.(2006) SNRs SNRs + reacceleration

39. Mean logarithm of CR atomic number Ankle scenario Experiment: KASKADE (Hörandel 2005) Yakutsk (Ivanov et al.2003) HiRes (Hörandel 2003) Dip scenario Precise measurements of CR composition is needed to discriminate two scenarios

40. Fireball model of Gamma-ray bursts Rees & Meszaros (1992) ForwardShock R Energy release (supernova ?) E ISM dΩ ~ 10-2 π Fireball Γ ≈ 100 Lorentz factor E ≈ 1051 erg(?) ESS≈ 3×1053 erg spherically symmetric analog Γ ~ (ESS/NISM)1/2 R-3/2 R ~ t1/4

41. CR acceleration in GRBs relativistic shock (Γ >> 1) Achterberg et al. (2001) assumption: isotropic CR diffusion in downstream region εmax≈ e BuΓ R c maximum proton energy unamplified magnetic field Bu = BISM = 10 μG εmax≈ 5 × 107mpc2 amplified magnetic field Bu2/8π = 0.1Γ2ρISMc2 εmax≈ 5 × 1013mpc2 NCR(ε)~ ε-γ γ≈ 2.2 GRBs are powerful extragalactic sources of CRs (?)

42. Problem Bd~ Γ2 Bu >> Bu strongly anisotropic CR diffusion low chance for CRs to recross shock from downstream to upstream inefficient CR production Bdll >> Bd┴ & downstream upstream (e.g. Ostrowski & Niemiec, 2006) VS Bd Bu shock

43. CR acceleration at late evolutionary stage (nonrelativistic shock) εmax≈ e Bu R c R(Γ = 1) =(ESS/3ρISMc2)1/3 ρISM = NISMmp InterStellar Medium density Bu2/8π = 0.1ρISMc2 amplified magnetic field For ESS= 3× 1053 erg, NISM = 1 cm-3 εmax = 3 × 1010 mpc2 However assumption Lγ = Qe, Pe~ Γ2ρISM c2 seems to be unrealistic Realistic numbers: Pp ~ Γ2ρISM c2 Pe = 10-2Pp then ESS≈1055 erg εmax ≈ 1011 mpc2

44. Active Galactic Nuclei Jets Powerful source of nonthermal emission Powerful source of Cosmic Rays Γ ≈ 10Lorentz factor Shear flow Effective frictional acceleration (e.g. Ostrowski, 2004) Shock Diffusive shock acceleration

45. Conclusions • CR acceleration in SNRs is able to provide the observed Galactic CR • spectrum up to the energy ε≈ 1017 eV • Two possibility for Galactic CR spectrum formation: • - Dip scenario ( CRs from Galactic SNRs at ε < 1017 eV + • Extragalactic CRs at ε > 1018 eV ) • - Ankle scenario ( CRs from Galactic SNRs at ε < 1017 eV + • Reaccelerated CRs at 1017 < ε < 1018 eV + • Extragalactic CRs at ε >019eV) • Precise measurements of CR spectrum and composition at ε > 1017 eV • are needed to discriminate the above two possibilities • Acceleration by subrelativistic/nonrelativistic shocks in GRBs • (or AGN jets) and frictional acceleration in AGN jets are • potential sources of Ultra High Energy CRs

46. Supernovae = star explosions lg( Luminosity) 0 H lines SN I SN II H lines -4 -8 300 0 100 200 t, day

47. SN Ia ( 15 % ) MCO<1.4MSun No central objects SNR in uniform ISM thermonuclear explosion SN II/Ib ( 85 %) MCO>1.4MSun pulsar / black hole SNR in CSM, modified by progenitor star wind core collapse ν detected from SN1987 A

48. Cosmic Ray Flux CR sources: Supernova remnants knee 1 Supernova remnants (?) Reacceleration (?) knee 2 Extragalactic (?) GZK cutoff (?)

49. Structure of the shock modified due to CR backreaction Flow speed u downstream upstream precursor CR pressure classical (unmodified) shock σ = u0/u2 = σS = u1/u2 =4 subshock modified shock σ > 4, σS < 4 x shock front p < mpc γ > 2 Acceleration sites p >> mpc γ < 2

50. Cutoff of CR spectrum due to CR interaction with CMB Zatcepin, Kuzmin (1966) Greisen (1966) Cosmic microwave background (CMB) radiation Galaxy CR source π± π0 E = 1030 eV E=6×1019 eV