1,183 research outputs found
A connection between accretion state and in an accreting neutron star: black hole-like soft state winds?
High resolution X-ray spectra of accreting stellar mass Black Holes reveal
the presence of accretion disc winds, traced by high ionisation Fe K lines.
These winds appear to have an equatorial geometry and to be observed only
during disc dominated states in which the radio jet is absent. Accreting
neutron star systems also show equatorial high ionisation absorbers. However,
the presence of any correlation with the accretion state has not been
previously tested. We have studied EXO 0748-676, a transient neutron star
system, for which we can reliably determine the accretion state, in order to
investigate the Fe K absorption/accretion state/jet connection. Not one of
twenty X-ray spectra obtained in the hard state revealed any significant Fe K
absorption line. However, intense Fe and Fe
(as well as a rarely observed Fe line plus S ; a blend of S and Ar ; Ca and Ca
, possibly produced by the same high ionisation
material) absorption lines ( eV, eV) are clearly detected during the only soft state
observation. This suggests that the connection between Fe K absorption and
states (and anticorrelation between the presence of Fe K absorption and jets)
is also valid for EXO 0748-676 and therefore it is not a unique property of
black hole systems but a more general characteristic of accreting sources.Comment: Accepted for publication in MNRAS Letter
The evolution of the disc variability along the hard state of the black hole transient GX 339-4
We report on the analysis of hard-state power spectral density function (PSD)
of GX 339-4 down to the soft X-ray band, where the disc significantly
contributes to the total emission. At any luminosity probed, the disc in the
hard state is intrinsically more variable than in the soft state. However, the
fast decrease of disc variability as a function of luminosity, combined with
the increase of disc intensity, causes a net drop of fractional variability at
high luminosities and low energies, which reminds the well-known behaviour of
disc-dominated energy bands in the soft state. The peak-frequency of the
high-frequency Lorentzian (likely corresponding to the high-frequency break
seen in active galactic nuclei, AGN) scales with luminosity, but we do not find
evidence for a linear scaling. In addition, we observe that this characteristic
frequency is energy-dependent. We find that the normalization of the PSD at the
peak of the high-frequency Lorentzian decreases with luminosity at all
energies, though in the soft band this trend is steeper. Together with the
frequency shift, this yields quasi-constant high frequency (5-20 Hz) fractional
rms at high energies, with less than 10 percent scatter. This reinforces
previous claims suggesting that the high frequency PSD solely scales with BH
mass. On the other hand, this constancy breaks down in the soft band (where the
scatter increases to ~30 percent). This is a consequence of the additional
contribution from the disc component, and resembles the behaviour of optical
variability in AGN.Comment: 12 pages, 8 figures, accepted for publication in MNRA
Tracing the reverberation lag in the hard state of black hole X-ray binaries
We report results obtained from a systematic analysis of X-ray lags in a
sample of black hole X-ray binaries, with the aim of assessing the presence of
reverberation lags and studying their evolution during outburst. We used
XMM-Newton and simultaneous RXTE observations to obtain broad-band energy
coverage of both the disc and the hard X-ray Comptonization components. In most
cases the detection of reverberation lags is hampered by low levels of
variability signal-to-noise ratio (e.g. typically when the source is in a soft
state) and/or short exposure times. The most detailed study was possible for GX
339-4 in the hard state, which allowed us to characterize the evolution of
X-ray lags as a function of luminosity in a single source. Over all the sampled
frequencies (~0.05-9 Hz) we observe the hard lags intrinsic to the power law
component, already well-known from previous RXTE studies. The XMM-Newton soft
X-ray response allows us to detail the disc variability. At low-frequencies
(long time scales) the disc component always leads the power law component. On
the other hand, a soft reverberation lag (ascribable to thermal reprocessing)
is always detected at high-frequencies (short time scales). The intrinsic
amplitude of the reverberation lag decreases as the source luminosity and the
disc-fraction increase. This suggests that the distance between the X-ray
source and the region of the optically-thick disc where reprocessing occurs,
gradually decreases as GX 339-4 rises in luminosity through the hard state,
possibly as a consequence of reduced disc truncation.Comment: 15 pages, 9 figures, 2 tables, accepted for publication in Ap
Weighing the black holes in ultraluminous X-ray sources through timing
We describe a new method to estimate the mass of black holes in Ultraluminous
X-ray Sources (ULXs). The method is based on the recently discovered
``variability plane'', populated by Galactic stellar-mass black-hole candidates
(BHCs) and supermassive active galactic nuclei (AGNs), in the parameter space
defined by the black-hole mass, accretion rate and characteristic frequency. We
apply this method to the two ULXs from which low-frequency quasi-periodic
oscillations have been discovered, M82 X-1 and NGC 5408 X-1. For both sources
we obtain a black-hole mass in the range 100~1300 Msun, thus providing evidence
for these two sources to host an intermediate-mass black hole.Comment: 5 pages, 2 figures, Accepted by MNRA
The truncated and evolving inner accretion disc of the black hole GX 339-4
The nature of accretion onto stellar mass black holes in the low/hard state
remains unresolved, with some evidence suggesting that the inner accretion disc
is truncated and replaced by a hot flow. However, the detection of relativistic
broadened Fe emission lines, even at relatively low luminosities, seems to
require an accretion disc extending fully to its innermost stable circular
orbit. Modelling such features is however highly susceptible to degeneracies,
which could easily bias any interpretation. We present the first systematic
study of the Fe line region to track how the inner accretion disc evolves in
the low/hard state of the black hole GX 3394. Our four observations display
increased broadening of the Fe line over two magnitudes in luminosity, which we
use to track any variation of the disc inner radius. We find that the disc
extends closer to the black hole at higher luminosities, but is consistent with
being truncated throughout the entire low/hard state, a result which renders
black hole spin estimates inaccurate at these stages of the outburst.
Furthermore, we show that the evolution of our spectral inner disc radius
estimates corresponds very closely to the trend of the break frequency in
Fourier power spectra, supporting the interpretation of a truncated and
evolving disc in the hard state.Comment: Accepted for publication in A&A. Some typos corrected from version
Revealing accretion onto black holes: X-ray reflection throughout three outbursts of GX 339-4
Understanding the dynamics behind black hole state transitions and the
changes they reflect in outbursts has become long-standing problem. The X-ray
reflection spectrum describes the interaction between the hard X-ray source
(the power-law continuum) and the cool accretion disc it illuminates, and thus
permits an indirect view of how the two evolve. We present a systematic
analysis of the reflection spectrum throughout three outbursts (500+
observations) of the black hole binary GX 339-4, representing the largest study
applying a self-consistent treatment of reflection to date. Particular
attention is payed to the coincident evolution of the power-law and reflection,
which can be used to determine the accretion geometry. The hard state is found
to be distinctly reflection weak, however the ratio of reflection to power-law
gradually increases as the source luminosity rises. In contrast the reflection
is found dominate the power-law throughout most of the soft state, with
increasing supremacy as the source decays. We discuss potential dynamics
driving this, favouring inner disc truncation and decreasing coronal height for
the hard and soft states respectively. Evolution of the ionisation parameter,
power-law slope and high-energy cut-off also agree with this interpretation.Comment: Accepted for publication in MNRA
The very faint hard state of the persistent neutron star X-ray binary SLX 1737-282 near the Galactic centre
We report on a detailed study of the spectral and temporal properties of the
neutron star low mass X-ray binary SLX 1737-282, which is located only ~1degr
away from Sgr A. The system is expected to have a short orbital period, even
within the ultra-compact regime, given its persistent nature at low X-ray
luminosities and the long duration thermonuclear burst that it has displayed.
We have analysed a Suzaku (18 ks) observation and an XMM-Newton (39 ks)
observation taken 7 years apart. We infer (0.5-10 keV) X-ray luminosities in
the range 3-6 x10^35erg s-1, in agreement with previous findings. The spectra
are well described by a relatively cool (kTbb = 0.5 keV) black body component
plus a Comptonized emission component with {\Gamma} ~1.5-1.7. These values are
consistent with the source being in a faint hard state, as confirmed by the ~
20 per cent fractional root mean square amplitude of the fast variability (0.1
- 7 Hz) inferred from the XMM-Newton data. The electron temperature of the
corona is >7 keV for the Suzaku observation, but it is measured to be as low as
~2 keV in the XMM-Newton data at higher flux. The latter is significantly lower
than expected for systems in the hard state. We searched for X-ray pulsations
and imposed an upper limit to their semi-amplitude of 2 per cent (0.001 - 7
Hz). Finally, we investigated the origin of the low frequency variability
emission present in the XMM-Newton data and ruled out an absorption dip origin.
This constraint the orbital inclination of the system to 65 degr unless the
orbital period is longer than 11 hr (i.e. the length of the XMM-Newton
observation).Comment: 7 pages, 4 figures, 1 table. Accepted for publication in MNRA
A tidal disruption flare in a massive galaxy? Implications for the fuelling mechanisms of nuclear black holes
We argue that the `changing look' AGN recently reported by LaMassa et al.
could be a luminous flare produced by the tidal disruption of a super-solar
mass star passing just a few gravitational radii outside the event horizon of a
nuclear black hole. This flare occurred in a massive,
star forming galaxy at redshift , robustly characterized thanks to
repeated late-time photometric and spectroscopic observations. By taking
difference-photometry of the well sampled multi-year SDSS Stripe-82
light-curve, we are able to probe the evolution of the nuclear spectrum over
the course of the outburst. The tidal disruption event (TDE) interpretation is
consistent with the very rapid rise and the decay time of the flare, which
displays an evolution consistent with the well-known behaviour (with
a clear superimposed re-brightening flare). Our analysis places constraints on
the physical properties of the TDE, such as the putative disrupted star's mass
and orbital parameters, as well as the size and temperature of the emitting
material. The properties of the broad and narrow emission lines observed in two
epochs of SDSS spectra provide further constraints on the circum-nuclear
structure, and could be indicative that the system hosted a moderate-luminosity
AGN as recently as a few years ago, and is likely undergoing residual
accretion as late as ten years after peak, as seen from the broad H
emission line. We discuss the complex interplay between tidal disruption events
and gas accretion episodes in galactic nuclei, highlighting the implications
for future TDE searches and for estimates of their intrinsic rates.Comment: 20 pages, 9 figures, 3 tables. Accepted for publication in MNRA
The peculiar Galactic center neutron star X-ray binary XMM J174457-2850.3
The recent discovery of a milli-second radio pulsar experiencing an accretion
outburst similar to those seen in low mass X-ray binaries, has opened up a new
opportunity to investigate the evolutionary link between these two different
neutron star manifestations. The remarkable X-ray variability and hard X-ray
spectrum of this object can potentially serve as a template to search for other
X-ray binary/radio pulsar transitional objects. Here we demonstrate that the
transient X-ray source XMM J174457-2850.3 near the Galactic center displays
similar X-ray properties. We report on the detection of an energetic
thermonuclear burst with an estimated duration of ~2 hr and a radiated energy
output of ~5E40 erg, which unambiguously demonstrates that the source harbors
an accreting neutron star. It has a quiescent X-ray luminosity of Lx~5E32 erg/s
and exhibits occasional accretion outbursts during which it brightens to
Lx~1E35-1E36 erg/s for a few weeks (2-10 keV). However, the source often
lingers in between outburst and quiescence at Lx~1E33-1E34 erg/s. This unusual
X-ray flux behavior and its relatively hard X-ray spectrum, a power law with an
index of ~1.4, could possibly be explained in terms of the interaction between
the accretion flow and the magnetic field of the neutron star.Comment: 10 pages, 3 figures, 2 tables, accepted to ApJ after minor revision
(provided a more detailed description of the long-term X-ray behavior in
Section 3.1 and Figure 1
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