Bibcode
Reig, P.; Torrejón, J. M.; Negueruela, I.; Blay, P.; Ribó, M.; Wilms, J.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 494, Issue 3, 2009, pp.1073-1082
Fecha de publicación:
2
2009
Revista
Número de citas
40
Número de citas referidas
33
Descripción
Context: The source 4U 2206+54 is one of the most enigmatic high-mass
X-ray binaries. In spite of intensive searches, X-ray pulsations have
not been detected in the time range 10-3-103 s. A
cyclotron line at ~30 keV has been suggested by various authors but
never detected with significance. The stellar wind of the optical
companion is abnormally slow. The orbital period, initially reported to
be 9.6 days, disappeared and a new periodicity of 19.25 days emerged.
Aims: The main objective of our RXTE monitoring of 4U 2206+54 is
to study the X-ray orbital variability of the spectral and timing
parameters. The new long and uninterrupted RXTE observations allow us to
search for long (~1 h) pulsations for the first time. Methods:
We divided the ~7-day observation into five intervals and obtained
time-averaged energy spectra and power spectral density for each
observation interval. We also searched for pulsations using various
algorithms. Results: We have discovered 5560-s pulsations in the
light curve of 4U 2206+54. Initially detected in RXTE data, these
pulsations are also present in INTEGRAL and EXOSAT observations. The
average X-ray luminosity in the energy range 2-10 keV is 1.5 ×
1035 erg s-1 with a ratio F_max/F_min ≈ 5. This
ratio implies an eccentricity of ~0.4, somewhat higher than previously
suggested. The power spectrum is dominated by red noise that can be
fitted with a single power law whose index and strength decrease with
X-ray flux. The source also shows a soft excess at low energies. If the
soft excess is modelled with a blackbody component, then the size and
temperature of the emitting region agrees with its interpretation in
terms of a hot spot on the neutron star surface. Conclusions: The
discovery of X-ray pulsations in 4U 2206+54 confirms the neutron star
nature of the compact companion and definitively rules out the presence
of a black hole. The source displays variability on time scales of days,
presumably due to changes in the mass accretion rate as the neutron star
moves around the optical companion in a moderately eccentric orbit. If
current models for the spin evolution in X-ray pulsars are correct, then
the magnetic field of 4U 2206+54 at birth must have been B ≳
1014 G.