Spectroscopy and Timing of the Middle-aged Pulsar B1055-52
M.A. Teter(Montana State Univ.),
D. Sanwal, G.G. Pavlov (Penn State),
V.E. Zavlin (MPE, Garching),
S. Tsuruta (Montana State Univ.),
R.N. Manchester (ATNF)
Abstract
The middle-aged radio, X-ray and gamma-ray pulsar B1055-52
(P = 197 ms,
yr)
was observed with Chandra
using the ACIS Continuous Clocking (CC) mode. This
observation, combined with the archival ROSAT data,
allows us to decompose the spectrum into 3 components -- a soft thermal
component with
eV and
km, a hard
thermal component with
eV and
m,
and a power-law component with a photon index
(the radii are given for a distance of 1 kpc).
The soft and hard thermal components can be interpreted as
radiation from the whole neutron star surface and
the polar caps, respectively, and the power-law component as
non-thermal emission from the pulsar magnetosphere.
Extension of the magnetospheric component to lower and higher energies
matches the 
-ray and optical spectra.
After correcting for instrumental effects, the absolute
timing for the ACIS/CC mode is accurate to about 3 milliseconds.
We find that the peak of the energy-resolved X-ray pulse
profiles from 0.5 keV to 2 keV matches the phase of the main
radio peak within the timing uncertainties.
Below 0.4 keV, the phase of the X-ray peak gradually shifts so that
for energy range 0.2 - 0.3 keV, it lags behind the radio peak
by about 0.25 in phase, similar to that observed in the
ROSAT data. Above 2.0 keV, the peak of the pulse profile
leads the radio peak by about 0.1 in phase. There is some evidence
for a second peak in the pulse profile for energies above 2.0 keV.
The energy-resolved light curves show variations in the shape
and pulsed fraction with energy. The phase-resolved spectral
analysis is presented as the phase dependence of various spectral
parameters. We will discuss interpretations of the data in
terms of neutron star models.
CATEGORY:
SUPERNOVAE, SUPERNOVA REMNANTS AND ISOLATED NEUTRON STARS
Himel Ghosh
2001-08-02