1 / 27

Physics of GRB Prompt emission

Physics of GRB Prompt emission. Asaf Pe’er University of Amsterdam. September 2005. Outline. Dynamics Basic facts Why relativistic expansion ? Constraints on the expansion Lorentz factor Fireball hydrodynamics: Time evolution The 4 different phases Radiative Processes

jacob-gross
Télécharger la présentation

Physics of GRB Prompt emission

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Physics of GRB Prompt emission Asaf Pe’er University of Amsterdam September 2005

  2. Outline • Dynamics • Basic facts • Why relativistic expansion ? • Constraints on the expansion Lorentz factor • Fireball hydrodynamics: Time evolution • The 4 different phases • Radiative Processes • Spectrum I: Simplified analysis • Complexities • Spectrum II: Modified analysis • Some open issues

  3. Basic Facts • g- ray flux: fg ~ 10-7 -10-5 erg cm-2 s-1 • eob. MeV • Cosmological distance: z=1  dL = 1028 cm  Liso,g = 4 p fg dL21050 – 1052 erg s-1 • Duration: few sec. • Variability: dt~ ms Example of a lightcurve (Thanks to Klaas Wiersema)

  4. Why relativistic expansion ? • Variability: dt ~ 1ms  Source size: R0 = cdt ~ 107 cm • Number density of photons at MeV: • Optical depth for pair production gg e±: Creation of e±, gg fireball !

  5. Why relativistic expansion ? • Photons accelerate the fireball. • In comoving frame: eco. = eob./G • Photons don’t have enough energy to produce pairs.

  6. Estimate of G (1) 100 MeV photons were observed  Idea: Optical depth to ~100 MeV photons ≤ 1 Mean free path for pair production (gg e±) by photon of comoving energy The (comoving) energy density in the BATSE range (20 keV – 2 MeV):

  7. qG-1 R Estimate of G (2) Constraint on source size in expanding plasma: Rdt relation: QxQ/10x

  8. Some complexities • The observed spectrum is NOT quasi-thermal • Small baryon load (enough >10-8 M) High optical depth to scattering Conclusion: Explosion energy is converted to baryons kinetic energy, which then dissipates to produce g-rays.

  9. Acceleration Coasting Self-similar: (Forward) shock GR GR0 GR-3/2 (R-1/2) Transition(Rev. Shock) Dissipation (Internal collisions,Shock waves) Stagesin dynamics of fireball evolution

  10. Acceleration Coasting Self-similar: (Forward) shock GR GR0 GR-3/2 (R-1/2) Transition(Rev. Shock) Dissipation (Internal collisions,Shock waves) Stagesin dynamics of fireball evolution

  11. Scaling law for an expanding plasma: I. Expansion phase • Conservation of entropy in adiabatic expansion: • Conservation of energy (obs. Frame): • Combined together:

  12. Acceleration Coasting Self-similar: (Forward) shock GR GR0 GR-3/2 (R-1/2) Transition(Rev. Shock) Dissipation (Internal collisions,Shock waves) Stagesin dynamics of fireball evolution

  13. Scaling law for an expanding plasma: II. Coasting phase • Fraction of energy carried by baryons: • Baryons kinetic energy: • Entropy conservation equation- holds

  14. v1, G1 v2,G2 dR0=cdt Extended emission: Shells collisions • The kinetic energy must dissipate. e.g.: • Magnetic reconnection • Internal collisions (among the propagating shells) • External collisions (with the surrounding matter) • Slow heating  Expansion as a collection of shells each of thickness R0

  15. Acceleration Coasting Self-similar: (Forward) shock GR GR0 GR-3/2 (R-1/2) Transition(Rev. Shock) Dissipation (Internal collisions,Shock waves) Stagesin dynamics of fireball evolution

  16. Radiation • Dissipation process: Unknown physics !!! • Characteristic (synchrotron) observed energy - • Characteristic inverse Compton (IC) energy- Most commonly used model:Synchrotron + inverse Compton (IC) • A fraction ee of the energy is transferred to electrons • eB - to magnetic field f~few Characteristic electrons Lorentz factor: magnetic field:

  17. Example of expected spectrum- optically thin case Inverse-Compton Component Synchrotron component

  18. Some complexities… Observational: • Clustering of the peak energy • Steep slopes at low energies Theoretical: • Dissipation at mild optical depth ? • Contribution from other radiative sources . • Unknown shock microphysics (ee,eB…) From Preece et. al., 2000

  19. “The compactness problem” Optically thin Synchrotron – IC emission model is incomplete ! Synchrotron spectrum extends above eob.syn~0.1 MeV  Possibility of pair production Compactness parameter: High compactness Large optical depth Put numbers: Or: eob.syn~0.1 MeV High Compactness !!

  20. Example of optically thin spectrum ? Inverse-Compton Component Synchrotron component

  21. Physical processes – dissipation phase: Electrons cool fast by Synchrotron and IC scattering – • Synchrotron (cyclotron) • Synchrotron self absorption • Inverse (+ direct !) Compton • Pair creation: gg e± • Pair annihilation: e+ + e- gg • Contribution of protons – p production (n’, high energy photons)

  22. Estimate of scattering optical depth by pairs Balance between pair production and annihilation Pair production rate – from energy considerations: Pair annihilation rate: At steady state: Conclusion: optical depth of (at least)t±≥ few is expected due to pairs!

  23. Spectrum at mild- high optical depth IC scattering by pairs: • Steep slopes in keV – MeV : 0.5 < a< 1 • epeak ~ MeV • High optical depth  Sharp cutoff at Gmec2 100 MeV

  24. Low energy distribution: quasi (but not) Maxwellian • Steep power law above q • . Electron distribution: high compactness l’ = 250 q=0.08 q = elec. temp. (in units of mec2)

  25. Spectrum as a function of compactness Estimate number of scattering required for thermalization: Spectrum dependence on the Optical depth  Compactness t± < few, l’≤few Optically thin spectrum t±>500, l’>105 Spectrum approach thermal Characteristic values – in between !!

  26. Summary • Dynamical evolution of GRB’s: different phases • Resulting spectrum : Complicated Low compactness High compactness Acceleration Coasting Self-similar: Dissipation

  27. q Estimate of G (Full calculation) • Given: Photons observed up to e1~100 MeV • Photons in the BATSE range (20 keV – 2 MeV): above MeV

More Related