1,666 research outputs found
IGR J14257-6117, a magnetic accreting white dwarf with a very strong X-ray orbital modulation
IGR J14257-6117 is an unclassified source in the hard X-ray catalogues.
Optical follow-ups suggest it could be a Cataclysmic Variable of the magnetic
type. We present the first high S/N X-ray observation performed by \XMM\ at
0.3--10 keV, complemented with 10--80 keV coverage by \Swift/BAT, aimed at
revealing the source nature. We detected for the first time a fast periodic
variability at 509.5\,s and a longer periodic variability at 4.05\,h, ascribed
to the white dwarf (WD) spin and binary orbital periods, respectively. These
unambiguously identify IGR J14257-6117 as a magnetic CV of the Intermediate
Polar (IP) type. The energy resolved light curves at both periods reveal
amplitudes decreasing with increasing energy, with the orbital modulation
reaching in the softest band. The energy spectrum shows optically
thin thermal emission with an excess at the iron complex, absorbed by two dense
media (), partially covering the X-ray
source. These are likely localised in the magnetically confined accretion flow
above the WD surface and at the disc rim, producing the energy dependent spin
and orbital variabilities, respectively. IGR J14257-6117, joins the group of
strongest orbitally modulated IPs now counting four systems. Drawing
similarities with low-mass X-ray binaries displaying orbital dips, these IPs
should be seen at large orbital inclinations allowing azimuthally extended
absorbing material fixed in the binary frame to intercept the line of sight.
For IGR J14257-6117, we estimate (). Whether
also the mass accretion rate plays a role in the large orbital modulations in
IPs cannot be established with the present data.Comment: Accepted for publication on MNRAS. 9 pages, 6 table, 5 figure
Spectral and timing properties of the accreting X-ray millisecond pulsar IGR J17498-2921
We analyze the spectral and timing properties of IGR J17498-2921 and the
characteristics of X-ray bursts to constrain the physical processes responsible
for the X-ray production in this class of sources. The broad-band average
spectrum is well-described by thermal Comptonization with an electron
temperature of kT_e ~ 50 keV, soft seed photons of kT_bb ~ 1 keV, and Thomson
optical depth \taut ~ 1 in a slab geometry. The slab area corresponds to a
black body radius of R_bb ~9 km. During the outburst, the spectrum stays
remarkably stable with plasma and soft seed photon temperatures and scattering
optical depth that are constant within the errors. This behavior has been
interpreted as indicating that the X-ray emission originates above the neutron
star (NS) surface in a hot slab (either the heated NS surface or the accretion
shock). The INTEGRAL, RXTE, and Swift data reveal the X-ray pulsation at a
period of 2.5 milliseconds up to ~65 keV. The pulsed fraction is consistent
with being constant, i.e. energy independent and has a typical value of 6-7%.
The nearly sinusoidal pulses show soft lags that seem to saturate near 10 keV
at a rather small value of ~ -60\mu s with those observed in other accreting
pulsars. The short burst profiles indicate that there is a hydrogen-poor
material at ignition, which suggests either that the accreted material is
hydrogen-deficient, or that the CNO metallicity is up to a factor of about two
times solar. However, the variation in the burst recurrence time as a function
of \dot{m} (inferred from the X-ray flux) is much smaller than predicted by
helium-ignition models.Comment: 9 pages, 8 figures, accepted for publication in A&A. arXiv admin
note: text overlap with arXiv:1012.022
The ephemeris, orbital decay, and masses of 10 eclipsing HMXBs
We take advantage of more than 10 years of monitoring of the eclipsing HMXB
systems LMC X-4, Cen X-3, 4U 1700-377, 4U 1538-522, SMC X-1, IGR J18027-2016,
Vela X-1, IGR J17252-3616, XTE J1855-026, and OAO 1657-415 with the ASM
on-board RXTE and ISGRI on-board INTEGRAL to update their ephemeris. These
results are used to refine previous measurements of the orbital period decay of
all sources (where available) and provide the first accurate values of the
apsidal advance in Vela X-1 and 4U 1538-522. Updated values for the masses of
the neutron stars hosted in the ten HMXBs are also provided, as well as the
long-term lightcurves folded on the sources best determined orbital parameters.
These lightcurves reveal complex eclipse ingresses and egresses, that are
understood mostly as being due to the presence of accretion wakes. The results
reported in this paper constitute a database to be used for population and
evolutionary studies of HMXBs, as well as theoretical modelling of long-term
accretion in wind-fed X-ray binaries.Comment: Accepted for publication on A&
The accretion environment of Supergiant Fast X-ray Transients probed with XMM-Newton
Supergiant fast X-ray transients (SFXTs) are characterized by a remarkable
variability in the X-ray domain, widely ascribed to the accretion from a clumpy
stellar wind. In this paper we performed a systematic and homogeneous analysis
of sufficiently bright X-ray flares from the SFXTs observed with XMM-Newton to
probe spectral variations on timescales as short as a few hundred of seconds.
Our ultimate goal is to investigate if SFXT flares and outbursts are triggered
by the presence of clumps and eventually reveal whether strongly or mildly
dense clumps are required. For all sources, we employ a technique developed by
our group, making use of an adaptive rebinned hardness ratio to optimally
select the time intervals for the spectral extraction. A total of twelve
observations performed in the direction of five SFXTs are reported. We show
that both strongly and mildly dense clumps can trigger these events. In the
former case, the local absorption column density may increase by a factor of
>>3, while in the latter case, the increase is only by a factor of 2-3 (or
lower). Overall, there seems to be no obvious correlation between the dynamic
ranges in the X-ray fluxes and absorption column densities in SFXTs, with an
indication that lower densities are recorded at the highest fluxes. This can be
explained by the presence of accretion inhibition mechanism(s). We propose a
classification of the flares/outbursts from these sources to drive future
observational investigations. We suggest that the difference between the
classes of flares/outbursts is related to the fact that the mechanism(s)
inhibiting accretion can be overcome more easily in some sources compared to
others. We also investigate the possibility that different stellar wind
structures, rather than clumps, could provide the means to temporarily overcome
the inhibition of accretion in SFXTs.Comment: Accepted for publication on A&
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