CAIXA: a catalogue of AGN in the<i>XMM</i>-<i>Newton</i>archive

Ponti, G.; Papadakis, I. E.; Bianchi, S.; Guainazzi, M.; Matt, Giorgio; Uttley, P.; Bonilla, Nuria Fonseca

doi:10.1051/0004-6361/201118326

Cited by 236 publications

(402 citation statements)

References 95 publications

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“…Previous studies have pointed out that the high-frequency PSD does not show a clear scaling with the luminosity/mass-accretion rate both in BHXRBs (Gierliński et al 2008) and AGN (O'Neil et al 2005;Zhou et al 2010;Ponti et al 2012). We observe that the high-frequency fractional rms of GX 339-4 is constant in the hard and very hard band (dominated by the hard X-ray Comptonization continuum) at any luminosity probed.…”

Section: The Scaling Of the High-frequency Psd With Luminosity In Bhxcontrasting

confidence: 44%

“…Indeed the high-frequency fractional rms (or equivalently the 'excess variance', e.g. Nikołajuk et al 2004;Ponti et al 2012), while being independent of the mass-accretion rate, scales inversely with the BH mass, with a very small scatter (which mostly depends on the uncertainty on M BH ), of the order of less than 0.2-0.4 dex (e.g. O'Neill et al 2005;Zhou et al 2010;Ponti et al 2012;Kelly et al 2011).…”

Section: The Scaling Of the High-frequency Psd With Luminosity In Bhxmentioning

confidence: 99%

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The evolution of the disc variability along the hard state of the black hole transient GX 339-4

Marco¹,

Ponti²,

Muñoz-Darias³

et al. 2015

Mon. Not. R. Astron. Soc.

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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.

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Section: The Scaling Of the High-frequency Psd With Luminosity In Bhxcontrasting

confidence: 44%

Section: The Scaling Of the High-frequency Psd With Luminosity In Bhxmentioning

confidence: 99%

The evolution of the disc variability along the hard state of the black hole transient GX 339-4

Marco¹,

Ponti²,

Muñoz-Darias³

et al. 2015

Mon. Not. R. Astron. Soc.

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“…The origin of this variability, which can be even large and fast (e.g., Matt et al 2003), is not fully understood yet (see e.g. McHardy et al 2006;Turner et al 2009;Ponti et al 2012). Variable absorption of the X-ray radiation along the line of sight is one of the possible explanations.…”

Section: Introductionmentioning

confidence: 99%

Anatomy of the AGN in NGC 5548

Gesu

Costantini

Ebrero

et al. 2015

A&A

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During an extensive multiwavelength campaign that we performed in 2013−2014, we found the prototypical Seyfert 1 galaxy NGC 5548 in an unusual condition of heavy and persistent obscuration. The newly discovered "obscurer" absorbs most of the soft X-ray continuum along our line of sight and lowers the ionizing luminosity received by the classical warm absorber. We present the analysis of the high resolution X-ray spectra collected with XMM-Newton and Chandra throughout the campaign, which are suitable to investigate the variability of both the obscurer and classical warm absorber. The time separation between these X-ray observations range from two days to eight months. On these timescales the obscurer is variable both in column density and in covering fraction. This is consistent with the picture of a patchy wind. The most significant variation occurred in September 2013 when the source brightened for two weeks. A higher and steeper intrinsic continuum and a lower obscurer covering fraction are both required to explain the spectral shape during the flare. We suggest that a geometrical change of the soft X-ray source behind the obscurer causes the observed drop in the covering fraction. Because of the higher soft X-ray continuum level, the September 2013 Chandra spectrum is the only X ray spectrum of the campaign in which individual features of the warm absorber could be detected. The spectrum shows absorption from Fe-UTA, O , and O , consistent with belonging to the lower-ionization counterpart of the historical NGC 5548 warm absorber.Hence, we confirm that the warm absorber has responded to the drop in the ionizing luminosity caused by the obscurer.

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“…3). This rather slow variability implies a relatively high black hole mass and following the prescription of [7] we calculate M BH = 2.5 × 10 7 M from the excess variance with a systematic error of 0.4 dex. It should be pointed out that the correlation of excess variance with M BH in [7] has been calculated using persistent AGN and the disk conditions, leading to the X-ray variability, are not necessarily the same in TDE.…”

Section: X-ray Light Curvementioning

confidence: 96%

“…This rather slow variability implies a relatively high black hole mass and following the prescription of [7] we calculate M BH = 2.5 × 10 7 M from the excess variance with a systematic error of 0.4 dex. It should be pointed out that the correlation of excess variance with M BH in [7] has been calculated using persistent AGN and the disk conditions, leading to the X-ray variability, are not necessarily the same in TDE. From the relationship of black hole mass to bulge K-band luminosity ( [6]) and using a bulge to total-light luminosity ratio for SDSS J1201+30 of 85% ( [13]), we find M BH = 1.8 × 10 7 M , in good agreement with the estimate based on variability.…”

Section: X-ray Light Curvementioning

confidence: 96%

A well-monitored, X-ray selected, tidal disruption event

Saxton

Read

Komossa

et al. 2012

EPJ Web of Conferences

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Abstract. We report on a candidate tidal disruption event detected in the XMM-Newton slew survey from the nucleus of SDSS J120136.02+300305.5 (z = 0.146; hereafter SDSS J1201+30). The source, monitored by Swift and XMM-Newton, was highly variable on timescales of a week, reaching a peak X-ray luminosity of 3 × 10 44 ergs/s. The light curve is reminiscent of the variations seen in SWIFT J1644+57, although in this case the absence of radio flux rules out a jet mechanism for the emission. The X-ray spectrum is steep, (spectral index = 3-5) and softens with diminishing flux. It is inconsistent with a single or multi-temperature black-body model but may be fit with Bremsstrahlung or comptonised thermal emission.

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CAIXA: a catalogue of AGN in theXMM-Newtonarchive

Cited by 236 publications

References 95 publications

The evolution of the disc variability along the hard state of the black hole transient GX 339-4

The evolution of the disc variability along the hard state of the black hole transient GX 339-4

Anatomy of the AGN in NGC 5548

A well-monitored, X-ray selected, tidal disruption event

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