SIMBAD references

We have completed part of a program to study the X-ray emission properties of old rotation-powered pulsars with XMM-Newton in order to probe and identify the origin of their X-radiation. The X-ray emission from these old pulsars is largely dominated by nonthermal processes. None of the observed spectra required adding a thermal component consisting of either a hot polar cap or surface cooling emission to model the data. The X-ray spectrum of PSR B0950+08 is best described by a single power law of photon index α=1.93^+0.14_–0.12. Taking optical data from the VLT FORS1 into account, a broken power-law model with the break point E_break=0.67^+0.18_–0.41keV and the photon indices α₁=1.27^+0.02_–0.01and α₂=1.88^+0.14_–0.11for E<E_break and E>E_break, respectively, is found to describe the pulsar's broadband spectrum from the optical to the X-ray band. Three σ temperature upper limits for possible contributions from a heated polar cap or the whole neutron star surface are T^∞_pc<0.87x10⁶ and T^∞_s<0.48x10⁶ K, respectively. We also find that the X-ray emission from PSR B0950+08 is pulsed with two peaks per rotation period. The phase separation between the two X-ray peaks is ∼144° (maximum to maximum), which is similar to the pulse peak separation observed in the radio band at 1.4 GHz. The main radio peak and the trailing X-ray peak are almost phase-aligned. The fraction of X-ray pulsed photons is ∼30%. A phase-resolved spectral analysis confirms the nonthermal nature of the pulsed emission and finds no spectral variations as a function of pulse phase. Detailed pulse profile simulations using the polar gap, the outer gap, and the two-pole caustic model constrain the pulsar's emission geometry to be that of an almost orthogonal rotator, for which the two-pole caustic model can reproduce the observed doubly peaked X-ray pulse profile. The spectral emission properties observed for PSR B0823+26 are similar to those of PSR B0950+08. Its energy spectrum is very well described by a single power law with photon index α=2.5^+0.9_–0.45. Three σ temperature upper limits for thermal contributions from a hot polar cap or from the entire neutron star surface are T^∞_pc<1.17x10⁶ and T^∞_s<0.5x10⁶ K, respectively. There is evidence for pulsed X-ray emission at the ∼97% confidence level with a pulsed fraction of 49%±22%. For PSR J2043+2740, which is located ∼1° outside the boundary of the Cygnus Loop, we report the first detection of X-ray emission. A power-law spectrum or a combination of a thermal and a power-law spectrum both yield acceptable descriptions of its X-ray spectrum. No X-ray pulses are detected from PSR J2043+2740 and the sensitivity is low–the 2 σ pulsed fraction upper limit is 57% assuming a sinusoidal pulse profile.