Pratik Majumdar SINP, Kolkata

1. Astroparticle Physics : High Energy Particles and Non Thermal Radiation Outline: • Cosmic rays • History and Discovery • Composition and propagation • Non thermal Radiation • How do we see cosmic rays ? Pratik Majumdar SINP, Kolkata Post MSc Lectures, December, SINP

2. Reading Materials • Longair : High Energy Astrophysics • T. Stanev : High Energy Cosmic Rays • T. Gaisser : Particle Physics and Cosmic rays • Many review articles on the subject Post MSc Lectures, December, SINP

3. Astroparticle Physics Dark matter Cosmic rays Solar neutrinos Gamma ray astronomy Neutrino masses Gravitational waves Beyond Standard Model Neutrino astronomy Cosmology Post MSc Lectures, December, SINP

4. What are cosmic rays ? • High Energy particles • Fully ionised atoms (98%, mainly Hydrogen and He) • < 1% Electrons and photons • Secondaries : high energy particles generated by interactions of cosmic rays in atmosphere • Achtung : more than 50,000 of such particles are going through you in < 30 mins • Particle identification in tracks of emulsion plates • Development of Geiger counters, Cloud chamber • Birth of Particle Physics in Cosmic rays ( 1920 to 1940 ) Post MSc Lectures, December, SINP

5. History of Cosmic rays • Wulf : expt. At Eiffel Tower • At 330 mts ionization decreased to 60% • Millikan named it “cosmic” -> gamma rays • Skobeltsyn recorded the first images in cloud chambers • Bothe and Kolhoerster designed the first coincidence technique to show they are indeed charged particles. (1929) Post MSc Lectures, December, SINP

6. History of Cosmic Rays: 1912 • 1912 Victor Hess • Investigated sources of radiation – took balloon up to 5000 meters • Found radiation increased after 2500 meters • This could be attributed to the fact that there was less atmosphere above to shield him from radiation • Thus he discovered that radiation is coming from space ... “cosmic radiation” • Won Nobel Prize in 1936 Hess after his flight, which he took without breathing apparatus in very cold and thin air!

7. What are cosmic rays (CRs)? • As it turns out, these charged particles are atomic nuclei zooming through space • Called “primary” CRs • Mostly protons or a (He) nuclei (other elements too, in much shorter supply) • There are more coming in at lower than higher energies • When these hit another nucleus in the atmosphere and stop, more particles are knocked downward, causing a cascading effect called a “shower” • Particles in the shower are called “secondary” CRs

8. Cosmic Ray “Showers” Space “Primary” Cosmic Ray (Ion, for example a proton) Earth’s atmosphere Atmospheric Nucleus p+ p- po “Secondary” Cosmic Rays... (about 50 produced after first collision) po g g p+ p- e+ e- g g m+ muon nm neutrino g e- Creating: Electromagnetic Shower Hadronic Shower Plus some:Neutrons Carbon-14 (mainly muons and neutrinos reach earth’s surface) (mainly g-rays)

9. Particle Physics  Cosmic Rays Electrons and positrons in cloud chambers Tracks in Spark Chambers Post MSc Lectures, December, SINP

10. Discovering Elementary particles Anderson and Neddermeyer discovered muons (1936) Blackett and others went to high altitudes, Pic du Midi obs. Nuclear emulsion plates Post MSc Lectures, December, SINP

11. Cosmic rays (1930-1945) First detection of Air showers Cosmic rays, gamma rays and neutrinos are all linked Post MSc Lectures, December, SINP

12. The Cosmic Ray Spectrum E2.7, mostly protons Knee solar modulation transition to heavier nuclei E3.1 mostly Fe? Ankle transition to lighter nuclei? Power Laws Shock Acceleration predicts FSource E2 ? Direct Measurements EAS Detectors 1 particle per m^2 per sec 1 particle per m^2 per year 1 particle per Km^2 per year LHC Post MSc Lectures, December, SINP

13. Open questions after 100years • What and where are the sources? • How do they work? • How are the particles really accelerated?... • …or due to new physics at large mass scales? • And how do cosmic rays manage to reach us? Post MSc Lectures, December, SINP

14. Composition • mainly protons (chemical composition similar to solar system) • Abundances provide information about origin and propagation • Nuclei with Z > 1 more abundant in cosmic rays than solar system • C,N,O, Fe are similar • Overabundance of Li, Be, B in cosmic rays Cosmic Rays Composition Post MSc Lectures, December, SINP

15. Primaries : Initially produced from H, He in stars • Secondaries : Produced from heavier nuclei ( C, N, O, Fe) • Overabundance of Li, Be, B produced due to Spallation Cosmic Rays Composition The existence (and the relative importance) of the secondary nucleons is an indication that the cosmic rays have crossed a certain amount of column density of order (of 1 interaction length) X ~ 10 g cm-2 Post MSc Lectures, December, SINP

16. Post MSc Lectures, December, SINP

17. Propagation in the Galaxy • Amount of matter traversed decreases as energy increases ; higher energy CRs spend less time • CRs propagate freely in containment volume with a constant probability to escape • Calculate average matter encountered during their lifetime in Galaxy • Taking into account simple Leaky box model Mean amount of matter λesc= τescρβc Confinement time ~ 106years Post MSc Lectures, December, SINP

18. Propagation in the Galaxy Contd… • If CRs travelled in straight path : L = t c  L ~ 1016 pc >> 15 Kpc (rgalaxy) CRs get deflected many times by the magnetic field Confinement in galaxy is a diffusive process which takes a long time. Post MSc Lectures, December, SINP

19. Diffusion of Cosmic rays • How diffusion occur ? Random scatterings by irregularities in magnetic field Fluctuations in the field. Diffusion loss equation : Exercise : Show this neglecting interactions , where energy loss -dE/dt = b(E) and Q(E,x,t ) is rate of injection of particles Post MSc Lectures, December, SINP

20. Propagation in the Galaxy Contd… • Leaky Box Model Cosmic rays in the Galaxy Cosmic rays injected Escape Time Solve for stationary state Observed Spectrum is different than Source spectrum Post MSc Lectures, December, SINP

21. More on Leaky Box Model • Consider no injection, spallation, energy loss/gain terms : • If particles diffuse : exponential, • If particles remain within confinement volume with characteristic escape time,  exponential distribution Post MSc Lectures, December, SINP

22. Number Density of Cosmic Rays Post MSc Lectures, December, SINP

23. Post MSc Lectures, December, SINP

24. Energy Density of Cosmic Rays Number density is then : Calculate energy density : Post MSc Lectures, December, SINP

25. Post MSc Lectures, December, SINP

26. Energetics to CR sources Post MSc Lectures, December, SINP

27. Possible sources • Typical flares from ordinary stars like Sun ~ 1034 ergs/sec • Consider all stars : not enough energy !!!! Supernova remnants ? Explosion rate ~ 1 per 30 yrs in our galaxy Supernova explosion energy ~ 1051ergs Supernova can supply energy to galacticcosmic rays ??? Post MSc Lectures, December, SINP

28. apparent source direction charged particle ,  nucleus + X ->+ X‘ 0->  ±->  +   -> e +  Origin of cosmic rays ? Summer Lectures, DESY, August 26th Berlin

29. Summer Lectures, DESY, August 26th Berlin

30. Multiwavelength Astronomy

31. optical (eV) optical view of our Galaxy Classical Astronomy “The passive Universe” Thermal radiation of T=3.000 - 10.000 K December 5th Kolkata

32. Infrared (10-2eV) (Spitzer) Classical Astronomy “The passive Universe” Thermal radiation of T=3.000 - 10.000 K underlying structure fully revealed in infrared image December 5th Kolkata

33. Non-thermal Astronomy“The revolutionary Universe” SN1987A • Violent, non-equilibrium processes in the Universe => non-thermal radiation • Energy stored in non-thermal radiation similar to energy in thermal radiation or magnetic fields => large contribution to energy balance and evolution of Cosmos December 5th Kolkata

34. Radio (10-6eV) Rotation axis Magnetic axis Radio Astronomy: “First window to violent universe” Cyg-A Crab jets inradio galaxies Radio waves emitted by synchrotron radiation of relativistic electrons gyrating in magnetic fields Pulsed radio emission from pulsars December 5th Kolkata

35. X-ray (103eV) (Chandra) X-ray Astronomy: Direct probe of high energy universe Crab Cyg-A hot intergalactic gas X-ray emission is bremsstrahlungof hot gas (T=107-108K) Non-thermal synchrotron radiation Sources: pulsars X-ray binaries AGNs ….. December 5th Kolkata

36. TeV Gamma-rays (1012eV) Very High Energy -ray Astronomy • Youngest astronomic discipline • First significant measurement of TeV -ray emission from Crab Nebula by Whipple telescope in 1989 • Flux Too Low • Numerous background from charged particles December 5th Kolkata

37. Next Lectures : We studied Cosmic rays and its propagation Next lecture : Acceleration of Cosmic rays What type of sources can accelerate cosmic rays ??? December 4th Berlin

38. Backup Slides December 4th Berlin

39. Post MSc Lectures, December, SINP

40. SNR Parameters • Mean ejecta speed : v = (2ESN/Mej)1/2 • Radius swept away : R = (3Mej/4Pr)1/3 • Sweep time : t0 = R/v • ISM density : r = 1.4mpnh Post MSc Lectures, December, SINP

41. Cosmic Rays • first & most direct evidence of non-thermal universe • plasma of particles with up to 1020eVin our own galaxy ??? 1912 discovered by Victor Hess Central Question in HE Astrophysics Victor Hess, 1911 Discovery of the Cosmic Radiation Origin still disputed in 2012 • Is there unambiguous evidence for the acceleration of hadrons in any or all cosmic sources? Post MSc Lectures, December, SINP