1,721,075 research outputs found
Extreme ULXs: super-Eddington accretors, or intermediate-mass black holes?
No full textUltraluminous X-ray sources (ULXs) with luminosities up to 2 imes 10(40)
erg s(-1) are now regarded as likely super-Eddington accretors powered by stellar mass black holes, and those above 10(41) erg s(-1) may be good intermediate-mass black hole (IMBH) candidates. However, the few objects lying between these ranges have an uncertain nature, and remain poorly studied. Here, we propose a new deep observation of one such object located within 20 Mpc. We will use the high quality EPIC data to determine whether its spectrum shows the characteristic signatures of the ultraluminous state, indicative of super-Eddington accretion onto large stellar black holes, or whether it appears consistent with the hard power-law spectra and > 10% fractional variability of an IMBH in the hard state
X-ray spectral states and metallicity of Ultra Luminous X-ray sources: a deeper insight into their spectral properties
Full text linkUltraluminous X-ray sources (ULXs) are a class of extragalactic, off nuclear and point-like sources with isotropic X-ray luminosities higher than 1e39 erg/s. They are supposed to be accreting Black Hole binaries systems but the accretion mechanisms at the basis of their extremely high X-ray luminosity are still matter of debate.
We carried out a detailed spectral analysis of all the available XMM-Newton observations of two ULXs in NGC 1313, adopting a common model based on a multicolor disc plus a comptonizing component. We were able to describe the spectral evolution of the two sources within such a common framework. Furthermore, we investigated the chemical abundances of their local environments making use of both EPIC and RGS data. The results appear to indicate sub-solar metallicity for both sources.
The possible existence of two spectral states in NGC 1313 X-1 and X-2 suggested to look for similar behaviours also in other ULXs. We then studied a larger sample of sources, including IC 342 X-1, NGC 5204 X-1, NGC 5408 X-1, Holmberg IX X-1, Holmberg II X-1, NGC 55 ULX1 and NGC 253 X-1. These sources were selected because they have a luminosity higher than 2e39 erg/s, are nearby, have one long observation and at least three other observations. The high quality observations provide at least 10000 counts in the EPIC instruments allowing us to constrain the curvature at high energy and to perform an analysis of the abundances of the material along the line of sight.
We found that, in most of the spectra of the sources of our sample, the high energy component has a low temperature and is optically thick. However, because of the poor quality of some observations, the spectral fits are sometimes affected by a degeneracy between the spectral parameters and the roll-over of the spectrum at high energy is not easy to detect. For these reasons, similarly to what has been done for low counting statistics spectra of Galactic X-ray binaries (XRBs), we adopted the method of the hardness ratios that has also the advantage to allow us to study the spectral variability in a way completely independent of the spectral models. This analysis suggests the existence of possible characteristic evolutionary patterns on the color-color and intensity-color diagrams linking at least two different spectral states. This behaviour can be explained in terms of a non-standard accretion disc in which the increment of the accretion rate produces outflows that become more and more important at the highest luminosities.
We tested the scenario of the ejection of a wind jointly analyzing the spectral and timing properties of the source NGC 55 ULX1 which shows a puzzling flux variability. In fact, fast drops in the flux are observed on time scales of minutes to hours that may be produced by optically thick blobs of matter that from time to time encounter our line of sight. We compared its variability properties with those of a Galactic accreting systems, EXO 0748-676, which is powered by a neutron star and is a known dipping source. We characterised the nature of the variability observed in the power density spectrum and, in particular, we checked the presence of a linear relation between the Root Mean Square (RMS) variability and the flux in several energy bands. We found that, in EXO 0748-676, the predominance of an (ionised) absorber strongly affects the RMS-flux relation which may anticorrelate when the absorption lines are unsaturated. On the other hand, no further variability is introduced when they are saturated and the variability is dominated by the accretion flow. In this case the source shows a positive correlation between RMS and flux.
Since we found an anticorrelation in NGC ULX1, we suggest that at the highest flux levels, massive and unsaturated turbulent outflows are ejected.
Finally, persistent ULXs, as those discussed above, do not allow us an easy comparison with the behaviour of Galactic XRBs. Transient ULXs are much more promising in this respect as they span different accretion regimes. Till now, only a handful of transient ULXs has been discovered and the link between them and the persistent sources is still unclear. We monitored the evolution of a new ULX (XMMU J004243.6+41251) discovered in January, 2012 in M31 by XMM-Newton. Its outburst showed that, at maximum luminosity, it entered in the ULX regime. It was then extensively followed by Swift during the flux decay. The source has experienced a fast rise in flux after discovery during which the XMM-Newton spectra changed from a powerlaw-like to a disk-like shape in the Swift spectra, suggesting a transition between the canonical low/hard and high/soft states. Its luminosity remained fairly constant for at least 40 days and then it faded below 1e38 erg/s. During the decay the disc emission softened and the temperature decreased from ~0.9 keV to ~0.5 keV.
An optical follow-up and the UVOT images failed to provide evidence of a counterpart down to 22 mag in the optical band and to 23-24 mag in the near Ultraviolet. We compared the properties of XMMU J004243.6+412519 with those of other known ULXs and Galactic black hole transients, finding more similarities with the latter
X-ray spectral states and metallicity in the ultraluminous X-ray sources NGC 1313 X-1 and X-2
No full textWe present a systematic analysis of the X-ray spectra of NGC 1313 X-1 and NGC 1313 X-2, using three years of XMM-Newton observations. We fitted the continuum with a Comptonization model plus a multicolour blackbody disc, which describes the effects of an accretion disc plus a corona. We checked the consistency of this spectral model on the basis of the variability patterns of its spectral parameters. We found that the two sources show different spectral states. We tentatively interpret the observed behaviour of NGC 1313 X-1 and X-2 within the framework of near-Eddington and/or super-Eddington accretion. We also attempted to determine the chemical abundances in the local environment of NGC 1313 X-1 and X-2 from the EPIC and RGS spectra. The results appear to indicate subsolar metallicity for both sources
Six years of XMM-Newton observations of NGC 1313 X-1 and X-2
No full textWe present a systematic analysis of the X-ray spectra of NGC 1313 X-1 and NGC 1313 X-2, using six years of XMM-Newton observations (17 observations). We fitted the continuum with a Comptonization model plus a multicolor blackbody disc, that describes the effects of an accretion disc plus an optically thick corona. We checked the consistency of this spectral model on the basis of the variability patterns of its spectral parameters. We found that the two sources show different spectral states. We tentatively interpret the observed behaviour of NGC 1313 X-1 within the framework of super-Eddington accretion and that of NGC 1313 X-2 within the framework of near Eddington accretion. We also attempted to determine the chemical abundances in the local environment of NGC 1313 X-1 and X-2, analyzing the RGS spectra of the longest observation available (122 ks). The results appear to indicate solar metallicity for the local environment of NGC 1313 X-1 and sub-solar metallicity for NGC 1313 X-2
Spectral variability in Swift and Chandra observations of the ultraluminous source NGC 55 ULX1
No full textNGC 55 ULX1 is a bright Ultraluminous X-ray source located 1.78 Mpc away. We analysed a sample of 20 Swift observations, taken between 2013 April and August, and two Chandra observations taken in 2001 September and 2004 June. We found only marginal hints of a limited number of dips in the light curve, previously reported to occur in this source, although the uncertainties due to the low counting statistics of the data are large. The Chandra and Swift spectra showed clearly spectral variability which resembles those observed in other ULXs. We can account for this spectral variability in terms of changes in both the normalization and intrinsic column density of a two-component model consisting of a blackbody (for the soft component) and a multicolour accretion disc (for the hard component). We discuss the possibility that strong outflows ejected by the disc are in part responsible for such spectral changes
Are jet ubiquitous in ULXs?
No full textA jet model represents well different X-ray states of the bright ULX IC342 X-1
A spectral-timing model for ULXs in the super-critical regime
No full textUltraluminous X-ray sources (ULXs) with luminosities lying between ~3x10^{39} - 2x10^{40} erg/s represent a contentious sample of objects as their brightness, together with a lack of unambiguous mass estimates for the vast majority of the central objects, leads to a degenerate scenario where the accretor could be a stellar remnant (black hole or neutron star) or intermediate mass black hole (IMBH). Recent, high-quality observations imply that the presence of IMBHs in the majority of these objects is unlikely unless the accretion flow somehow deviates strongly from expectation based on objects with known masses. On the other-hand, physically motivated models for super-critical inflows can re-create the observed X-ray spectra and their evolution, although have been lacking a robust explanation for their variability properties. In this paper we include the effect of a partially inhomogeneous wind that imprints variability onto the X-ray emission via two distinct methods. The model is heavily dependent on both inclination to the line-of-sight and mass accretion rate, resulting in a series of qualitative and semi-quantitative predictions. We study the time-averaged spectra and variability of a sample of well-observed ULXs, finding that the source behaviours can be explained by our model in both individual cases as well as across the entire sample, specifically in the trend of hardness-variability power. We present the covariance spectra for these sources for the first time, which shed light on the correlated variability and issues associated with modelling broad ULX spectra
Ultraluminous X-ray sources: a deeper insight into their spectral evolution
No full textWe select a sample of nearby ultraluminous X-ray sources with long XMM-Newton observations and analyse all the available XMM-Newton data using both X-ray spectral fitting techniques and hardness-intensity diagrams. The sample includes IC 342 X-1, NGC 5204 X-1, NGC 5408 X-1, Holmberg IX X-1, Holmberg II X-1, NGC 1313 X-1, NGC 1313 X-2 and NGC 253 X-1. We found that, although a common reference model can be used to describe the X-ray spectra, the sources show different spectral evolutions, phenomenologically described in terms of variations in the properties of a soft component and a high-energy tail. Variations at low energies are accounted for (mostly) by changes in the normalization of the soft component and/or in the column density to the source, while variations in the high-energy tail by changes in the parameters of an optically thick corona. This spectral variability is rather well characterized on a colour-colour and hardness-intensity diagram in terms of suitably defined hardness ratios. We suggest the existence of a variability pattern on the hardness-intensity diagram and we interpret it in terms of the switch between a near-Eddington and a super-Eddington accretion regime. The transition between the two regimes seems to be driven mostly by changes in the contribution of the soft component, which can be explained in terms of the increasing importance of wind emission. The analysis is complemented by an investigation of the short-term time variability of all the sources. In general, no clear correlation between the spectral and temporal properties is found
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