Diffusive Particle Acceleration (DSA) in Relativistic Shocks

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Diffusive Particle Acceleration (DSA) in Relativistic Shocks Don Ellison & Don Warren (NCSU), Andrei Bykov (Ioffe Institute) 1) Monte Carlo simulation of Diffusive Shock Acceleration (DSA) in collisionless shocks of arbitrary speed. 2) Includes non-linear feedback of particle pressure on shock structure, and consistent thermal injection model 3) Can do all shock speeds but emphasize trans-relativistic shocks a) GRB afterglows b) Type Ibc supernovae with long-duration X-ray transients and mildly relativistic ejecta 4) Here, only consider protons in parallel, steady-state shocks 5) Don Warren in next talk discusses electron acceleration For details and references to extensive literature on relativistic shocks, see Ellison, Warren & Bykov, ApJ 2013 1

1) Non-relativistic shocks (flow speed << c) are known to be efficient particle accelerators. Famous test-particle power law : f ( p) p 2) Relativistic shocks are harder to study mathematically because they have highly anisotropic particle distributions Require Simulations a) Particle-In-Cell (PIC) b) Monte Carlo 3) PIC has great advantage in that the plasma physics is done consistently: shock creation, B-field generation, particle diffusion & acceleration, for electrons and protons, all done self-consistently 4) However, computation time strong limit for PIC, particularly with 3-D requirement for cross-field diffusion small dynamic range 5) Monte Carlo assumes scattering law ( gyro-radius) allows large dynamic range but must parameterize plasma physics 6) Use Monte Carlo to investigate non-linear effects from efficient DSA for applications that require large dynamic range, e.g., ultra-high-energy CRs 3 r/( r 1) 2

p 4 f(p) Test-Particle results : Test-particle results: 0 = 10 1) For V sk << c, strong shock has compression ratio r ~ 4 and f(p) p -4 (phase-space) 0 = 1.5 Non-rel 2) For V sk ~ c, r ~ 3 and f(p) p -4.23 3) Trans-rel. shock ( 0 ~ 1.5 3 ) f(p) in between 1) For trans-relativistic & fully relativistic speeds, all results depend on details of plasma physics, i.e., wave-particle interactions in self-generated magnetic turbulence parameterize in Monte Carlo 2) BUT, if application assumes acceleration is efficient (e.g., GRBs) Cosmic Rays must modify shock structure Non-linear shock structure calculated in Monte Carlo Don Ellison, Texas Symposium 3

p 4 f(p) Flow speed Non-relativistic shock Test-particle f(p) Shock structure modified by CR backpressure Energy & momentum conserving non-linear f(p) Cosmic ray acceleration can strongly modify shock structure in non-relativistic shocks Position, x Don Ellison, Texas Symposium 4

p 4 f(p) Flow speed Fully relativistic shock, 0 = 10 Test-particle f(p) Shock structure modified by CR backpressure Energy & momentum conserving non-linear f(p) Amount of shock modification depends on injection efficiency and strength of B-field turbulence. Position, x 5

Are approximations required by Monte Carlo too extreme to yield useful results? Look at direct comparison between Monte Carlo results and Particle-in-Cell (PIC) simulation of Sironi & Spitkovsky 2011 protons Sironi & Spitkovsky 2011 Quasi-parallel PIC simulation: Angle between shock normal and B-field: = 15 0 Shock Lorentz factor: 0 = 15 electrons p, e m e /m p Don Ellison, Texas Symposium 6

Density vs. position Sironi & Spitkovsky 2011 Shock smoothing Ellison, Warren & Bykov 2013 Flow speed vs. position DS UpS dn/d DS UpS Acceleration efficiency good match p, e m e /m p Sironi & Spitkovsky 2011 protons p 7

p 4 f(p) If shock slows from fully relativistic to trans-relativistic to non-relativistic (as in GRB afterglow), expect transition from soft power law to highly modified concave spectrum Basic assumptions: Magnetic turbulence, with required scales, can be generated by accelerated particles in shock precursor Simple description of wave-particle interactions used in MC ( gyroradius) is a reasonable approximation Plane-parallel shock geometry OK for first-step (suggested by quasi-parallel PIC results) Enough particles are injected to have efficient acceleration Don Ellison, Texas Symposium 8

p 4 f(p) Fully relativistic shock with Large-Angle-Scattering Test-particle f(p) Fully relativistic shock with fine scattering Energy & momentum conserving nonlinear f(p) Assumptions for plasma physics strongly impact results, BUT, independent of any assumption, if acceleration is efficient, non-linear effects must be taken into account Don Ellison, Texas Symposium 9

Conclusions: 1) If relativistic shocks accelerate particles efficiently, non-linear back reaction of cosmic rays (CRs) on shock must be taken into account 2) Assuming efficient CR production, there must be a transition between non-relativistic shocks with hard, concave spectra, and fully relativistic shocks with softer spectra 3) Trans-relativistic shocks ( 0 ~ 1.5 3) may be important for GRB afterglows and subclass of Type Ibc supernova with relativistic ejecta speeds (e.g., Soderberg et al 2006) 4) To model observations must accelerated electrons consistently with ions and calculate radiation transformed to observer frame Stay for talk by Don Warren with preliminary work applying non-linear DSA to GRB afterglow emission For details and references to extensive literature on relativistic shocks, see Ellison, Warren & Bykov, ApJ 2013 Don Ellison, Texas Symposium 10

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