Vela pulsar and its synchrotron nebula

We present high-resolution Chandra X-ray observations of PSR B0833-45, the 89 ms pulsar associated with the Vela supernova remnant. We have acquired two observations separated by 1 month to search for changes in the pulsar and its environment following an extreme glitch in its rotation frequency. We find a well-resolved nebula with a toroidal morphology remarkably similar to that observed in the Crab Nebula, along with an axial Crab-like jet. Between the two observations, taken ~3 × 105 s and ~3 × 106 s after the glitch, the flux from the pulsar is found to be steady to within 0.75%; the 3 σ limit on the fractional increase in the pulsar's X-ray flux is 10-5 of the inferred glitch energy. We use this limit to constrain parameters of glitch models and neutron star structure. We do find a significant increase in the flux of the nebula's outer arc; if associated with the glitch, the inferred propagation velocity is 0.7c, similar to that seen in the brightening of the Crab Nebula wisps. We propose an explanation for the X-ray structure of the Vela synchrotron nebula based on a model originally developed for the Crab Nebula. In this model, the bright X-ray arcs are the shocked termination of a relativistic equatorial pulsar wind that is contained within the surrounding kidney-bean shaped synchrotron nebula comprising the postshock, but still relativistic, flow. In a departure from the Crab model, the magnetization parameter σ of the Vela pulsar wind is allowed to be of order unity; this is consistent with the simplest MHD transport of magnetic field from the pulsar to the nebula, where B ≤ 4 × 10-4 G. The inclination angle of the axis of the equatorial torus with respect to the line of sight is identical to that of the rotation axis of the pulsar as previously measured from the polarization of the radio pulse. The projection of the rotation axis on the sky may also be close to the direction of proper motion of the pulsar if previous radio measurements were confused by orthogonal-mode polarized components. We review effects that may enhance the probability of alignment between the spin axis and space velocity of a pulsar, and speculate that short-period, slowly moving pulsars are just the ones best-suited to producing synchrotron nebulae with such aligned structures. Previous interpretations of the compact Vela nebula as a bow-shock in a very weakly magnetized wind suffered from data of inadequate spatial resolution and less plausible physical assumptions.

[1]  D. Helfand,et al.  Pulsar timing. I. Observations from 1970 to 1978. , 1980 .

[2]  E. Harrison,et al.  Acceleration of pulsars by asymmetric radiation , 1975 .

[3]  M. Ruderman Neutron Starquakes and Pulsar Periods , 1969, Nature.

[4]  R. Romani,et al.  $\gamma$-Ray Pulsars: Emission Zones and Viewing Geometries, A Computer Animation , 1994, astro-ph/9401045.

[5]  H. Ögelman,et al.  Pulsed X-rays from the Vela pulsar , 1993, Nature.

[6]  W. Suen,et al.  The Thermal Response of a Pulsar Glitch: The Nonspherically Symmetric Case , 1998, gr-qc/9903033.

[7]  V. Kaspi,et al.  Glitches in Southern Pulsars , 2000, astro-ph/0005561.

[8]  O'Dell,et al.  Discovery of Spatial and Spectral Structure in the X-Ray Emission from the Crab Nebula , 2000, The Astrophysical journal.

[9]  P. E. Reichley,et al.  Second Decrease in the Period of the Vela Pulsar , 1971 .

[10]  Kenneth R. Sembach,et al.  The Distance to the Vela Supernova Remnant , 1999, astro-ph/9902230.

[11]  P. McCulloch,et al.  Detection of change in rotation measure of the Vela pulsar , 1977, Nature.

[12]  John H. Chappell,et al.  AXAF High-Resolution Camera (HRC): calibration and recalibration at XRCF and beyond , 1997, Optics & Photonics.

[13]  Alexander Brown,et al.  High-resolution, far-ultraviolet study of Beta Draconis (G2 Ib-II) - Transition region structure and energy balance , 1984 .

[14]  R. Manchester The shape of pulsar beams , 1995 .

[15]  D. Frail,et al.  Does the VELA Pulsar Have ``Wisps''? , 1991 .

[16]  D. Lorimer,et al.  High birth velocities of radio pulsars , 1994, Nature.

[17]  H. Ögelman,et al.  ROSAT Observations of the Vela Pulsar , 1999, astro-ph/0004015.

[18]  H. Ögelman,et al.  An X-ray jet from the Vela pulsar , 1995, Nature.

[19]  Alan M. Watson,et al.  WFPC2 Studies of the Crab Nebula. I. HST and ROSAT Imaging of the Synchrotron Nebula , 1995 .

[20]  G. Downs,et al.  Intensity dependence of the pulse profile and polarization of the Vela pulsar , 1983 .

[21]  D. Helfand,et al.  Pulsar timing .III. Timing noise of 50 pulsars. , 1980 .

[22]  K. Nomoto,et al.  Thermal Response of a Neutron Star to a Glitch , 1997 .

[23]  D. Bock,et al.  A High-Resolution Radio Survey of the Vela Supernova Remnant , 1998, astro-ph/9807125.

[24]  E. Phinney,et al.  Birth kicks as the origin of pulsar rotation , 1998, Nature.

[25]  C. Kennel,et al.  Magnetohydrodynamic model of Crab nebula radiation , 1984 .

[26]  J. Cordes,et al.  Pulsar Jets: Implications for Neutron Star Kicks and Initial Spins , 2000, astro-ph/0007272.

[27]  K. Cheng,et al.  A Tool for Probing the Structure of Neutron Stars: Transient X-Ray Emission , 1994 .

[28]  F. R. Harnden,et al.  Einstein observations of the Vela supernova remnant - the spatial structure of the hot emitting gas , 1985 .

[29]  R. Epstein,et al.  Soft X-ray pulses from neutron star glitches , 1991 .

[30]  A. Harding,et al.  OSSE Detection of Gamma Rays from the VELA Synchrotron Nebula , 1996 .

[31]  F. R. Harnden,et al.  The X-Ray Structure of the VELA X Region Observed from UHURU , 1973 .

[32]  A. Lyne,et al.  The Parkes southern pulsar survey - III. Timing of long-period pulsars , 1998 .

[33]  A. Harding,et al.  A Rossi X-Ray Timing Explorer Observation of the Vela Pulsar: Filling in the X-Ray Gap , 1999, astro-ph/9904357.

[34]  J. Gunn,et al.  The Origin of the Magnetic Field and Relativistic Particles in the Crab Nebula , 1974 .

[35]  E. Gotthelf,et al.  A Spatially Resolved Plerionic X-Ray Nebula around PSR B0540–69 , 2000, The Astrophysical journal.

[36]  P. Anderson,et al.  Pulsar glitches and restlessness as a hard superfluidity phenomenon , 1975, Nature.

[37]  A. Deshpande,et al.  Pulsar Magnetospheric Emission Mapping: Images and Implications of Polar Cap Weather , 1999, astro-ph/9909398.

[38]  Kaiyou Chen,et al.  Neutron Star Magnetic Field Evolution, Crust Movement, and Glitches , 1997, astro-ph/9709008.

[39]  E. Tademaru Acceleration of pulsars by asymmetric radiation. III. Observational evidence , 1977 .

[40]  D. Pines,et al.  THE LARGE GLITCH FROM PSR 0355+54 AND ITS POST-GLITCH RELAXATION , 1988 .

[41]  B. Aschenbach,et al.  Temporal Variability of the X-Ray Emission of the Crab Nebula Torus , 1998, astro-ph/9808208.

[42]  R. Chevalier A Model for the X-Ray Luminosity of Pulsar Nebulae , 2000 .

[43]  R. Norris,et al.  The proper motions of six southern radio pulsars , 1990 .

[44]  J. Cordes,et al.  JPL pulsar timing observations. III. Pulsar rotation fluctuations. , 1985 .

[45]  F. R. Harnden,et al.  Einstein observations of Vela X and the Vela pulsar , 1985 .