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Luca Del Zanna Gruppo Plasmi Astrofisici Dipartimento di Astronomia e Scienza dello Spazio

Relativistic MHD simulations of Pulsar Wind Nebulae: on the origin of the inner jet-torus structure. Luca Del Zanna Gruppo Plasmi Astrofisici Dipartimento di Astronomia e Scienza dello Spazio Università degli Studi di Firenze. Introduction. Active Galactic Nuclei Compact X-ray sources

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Luca Del Zanna Gruppo Plasmi Astrofisici Dipartimento di Astronomia e Scienza dello Spazio

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  1. Relativistic MHD simulations of Pulsar Wind Nebulae: on the origin of the inner jet-torus structure Luca Del Zanna Gruppo Plasmi Astrofisici Dipartimento di Astronomia e Scienza dello Spazio Università degli Studi di Firenze L. Del Zanna: Relativistic MHD simulations of PWNe

  2. Introduction • Active Galactic Nuclei • Compact X-ray sources • Gamma-Ray Bursts • Pulsar Wind Nebulae Relativistic flows and shocks in high-energy astrophysics: Problem: 3-D dynamics of relativistic plasmas Solution: shock-capturing codes for relativistic MHD L. Del Zanna: Relativistic MHD simulations of PWNe

  3. Relativistic MHD equations • Equations written in covariant form: • where: In the following we shall consider special relativity L. Del Zanna: Relativistic MHD simulations of PWNe

  4. Shock-capturing numerical schemes • grid discretization (finite volumes or differences) • reconstruction of U and F at intercells (TVD, ENO) • approximate Riemann solver for fluxes (upwind step) • time integration (two-steps or higher order RK) Any set of hyperbolic conservation laws may be solved by high-order Godunov schemes: Problem: MHD and RMHD systems are not strictly hyperbolic L. Del Zanna: Relativistic MHD simulations of PWNe

  5. The divergence-free condition The equation for the B field yields, as in classical MHD: • CT staggered discretization (Evans & Hawley, 1988) • staggered B components in fluxes (to avoid monopoles) • four-state numerical magnetic fluxes the specific operator structure (a curl) in the induction equation must be considered to preserve the constraint We use the Upwind Constrained Transport method for MHD (UCT: Londrillo & Del Zanna, 2000; 2004) L. Del Zanna: Relativistic MHD simulations of PWNe

  6. A central-type scheme for relativistic MHD • A new central-type shock-capturing scheme for RMHD (Del Zanna & Bucciantini, 2002; Del Zanna, Bucciantini & Londrillo, 2003) • RMHD code main features: • Third order accuracy in time, unsplit (Runge-Kutta) • Third order accuracy in space (Convex-ENO + MC limiter) • Simplified Riemann solver (central scheme, no characteristic waves) • Efficient inversion from conservative to primitive variables • UCT staggered method for •B=0 (preserved to machine accuracy) • Generalized orthogonal curvilinear coordinates • F90 modular structure, parallelization with MPI • Future work: AMR and GRMHD L. Del Zanna: Relativistic MHD simulations of PWNe

  7. Pulsar Wind Nebulae • PWNe are hot bubbles (plerions) emitting synchrotron radiation at all wavelengths (e.g. Crab) • Originated by the interaction of the ultra-relativistic magnetized pulsar wind with the expanding SNR dense ejecta • Theory is based on 1-D analytic (Kennel & Coroniti, 1984) and self-similar (Emmering & Chevalier, 1987) MHD models L. Del Zanna: Relativistic MHD simulations of PWNe

  8. PWN and SNR: structure and evolution • a: wind termination shock • b: PWN-SNR contact discontinuity • c: shell of swept up ejecta • d: reverse shock • e: SNR-ISM contact discontinuity • f: SNR blast wave CD TS PWN SNR reverberations Sedov free expansion L. Del Zanna: Relativistic MHD simulations of PWNe

  9. Jet-torus structure: Chandra X-ray images • Crab nebula (Weisskopf et al., 2000; Hester et al., 2002) • Vela pulsar (Helfand et al., 2001; Pavlov et al., 2003) • Other objects: PSR 1509-58, G0.9+01, G54.1+0.3 Crab Vela L. Del Zanna: Relativistic MHD simulations of PWNe

  10. Jet-torus structure: theory • Torus: KC84 + higher equatorial wind energy flux? • Jets: magnetic collimation not efficient for >>1: are they launched downstream of the TS? • Bogovalov & Khangoulian, 2002 • Lyubarsky, 2002 • Axisymmetric RMHD simulations of the interaction of an anisotropic relativistic magnetized wind with SN ejecta • Komissarov & Lyubarsky, 2003 • Del Zanna, Amato & Bucciantini, submitted L. Del Zanna: Relativistic MHD simulations of PWNe

  11. Pulsar relativistic wind model • Far from the pulsar light cylinder the wind is expected to be ultrarelativistic, cold, and weakly magnetized. We assume: • Isotropic mass flux, anisotropic energy flux • Purely toroidal magnetic field (residual field in a striped wind): • Parameters of the wind model: L. Del Zanna: Relativistic MHD simulations of PWNe

  12. Simulation setup • Central-type conservative RMHD code (here second order) • Spherical geometry, axial symmetry (r,) • Poloidal velocity and purely toroidal magnetic field • Computational grid: 400 points in r, 100 in  • Boundaries: injection for r=0.05 ly, extrapolation for r=20 ly • Long time simulations (beginning of reverberation phase) • High accuracy near the center: extremely small timesteps! • Initial conditions: • Pulsar ultrarelativistic wind • Spherical shell of expanding dense ejecta • Static unmagnetized ISM L. Del Zanna: Relativistic MHD simulations of PWNe

  13. PWN self-similar evolution and TS shape • Expected TS profile: L. Del Zanna: Relativistic MHD simulations of PWNe

  14. PWN elongation • Magnetic pinching effect (Begelman & Li, 1992): L. Del Zanna: Relativistic MHD simulations of PWNe

  15. TS structure and flow pattern • The wind anisotropy shapes the TS structure. A complex flow pattern arise: • A: ultrarelativistic pulsar wind • B: subsonic equatorial outflow • C: supersonic equatorial funnel • D: super-fastmagnetosonic flow • a: termination shock front • b: rim shock • c: fastmagnetosonic surface =0.003 L. Del Zanna: Relativistic MHD simulations of PWNe

  16. Formation of polar jets by hoop stresses • The flow pattern changes drastically with increasing  • For high magnetization (>0.01) a supersonic jet is formed =0.003 =0.01 =0.03 L. Del Zanna: Relativistic MHD simulations of PWNe

  17. PWN crunching by instabilities at CD L. Del Zanna: Relativistic MHD simulations of PWNe

  18. Dependence on the field shape • Initial magnetic field with a narrow equatorial neutral sheet b=10 L. Del Zanna: Relativistic MHD simulations of PWNe

  19. Summary and conclusions • Many PWNe show a jet-torus structure (Crab, Vela, …) • The torus is explained with a higher equatorial energy flux • The jet poses severe theoretical difficulties, as collimation is not effective in the wind: hoop stresses inside PWN? • RMHD axisymmetric simulations confirm this scenario: • The TS has a toroidal shape, a strong equatorial flow is produced • For >0.01 hoop stresses divert the flow toward the axis • Plasma is compressed and a polar jet with v=0.5-0.7c is launched • CD instabilities driven by large vortexes may crunch the PWN • A neutral equatorial sheet is enough to prevent the crunching Thank you L. Del Zanna: Relativistic MHD simulations of PWNe

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