The X-ray Spectrum of the Vela Pulsar Resolved with Chandra
Abstract
We report the results of the spectral analysis of two observations of the Vela pulsar with the Chandra X-ray observatory. The spectrum of the pulsar does not show statistically significant spectral lines in the observed 0.25-8.0 keV band. Similar to middle-aged pulsars with detected thermal emission, the spectrum consists of two distinct components. The softer component can be modeled as a magnetic hydrogen atmosphere spectrum - for the pulsar magnetic field B=3× 1012 G and neutron star mass M=1.4 M and radius R∞ =13 km, we obtain ∞ =0.68 0.03 MK, L bol∞ = (2.6 0.2)× 1032 erg s-1, d=210 20 pc (the effective temperature, bolometric luminosity, and radius are as measured by a distant observer). The effective temperature is lower than that predicted by standard neutron star cooling models. A standard blackbody fit gives T∞ =1.49 0.04 MK, L bol∞=(1.5 0.4)× 1032 d2502 erg s-1 (d250 is the distance in units of 250 pc); the blackbody temperature corresponds to a radius, R∞ =(2.1 0.2) d250 km, much smaller than realistic neutron star radii. The harder component can be modeled as a power-law spectrum, with parameters depending on the model adopted for the soft component - γ=1.5 0.3, Lx=(1.5 0.4)× 1031 d2502 erg s-1 and γ=2.7 0.4, Lx=(4.2 0.6)× 1031 d2502 erg s-1 for the hydrogen atmosphere and blackbody soft component, respectively (γ is the photon index, Lx is the luminosity in the 0.2--8 keV band). The extrapolation of the power-law component of the former fit towards lower energies matches the optical flux at γ 1.35--1.45.
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