Anatomy of the AGN in NGC 5548

Gesu, Laura Di; Costantini, E.; Ebrero, J.; Mehdipour, M.; Kaastra, J. S.; Ursini, F.; Petrucci, Pierre-Olivier; Cappi, M.; Kriss, G. A.; Bianchi, S.; Branduardi‐Raymont, G.; Marco, Barbara De; Rosa, A. De; Kaspi, S.; Paltani, S.; Pinto, C.; Ponti, G.; Steenbrugge, K. C.; Whewell, M.

doi:10.1051/0004-6361/201525934

Cited by 38 publications

(41 citation statements)

References 66 publications

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“…We note that during the first three archival observations, when the source was unobscured, the best-fit parameters of our Cloudy models converged into a two-component warm absorber solution that is consistent with the values reported by the Suzaku data , and which were considered a good approximation, at low energy resolution, of the multi-temperature warm absorber detected in grating Chandra and XMM-Newton spectra (Andrade-Velazquez et al 2010;Steenbrugge et al 2005;Paper VI). During the campaign, our best-fit values are overall in agreement with the average values found by Paper 0 and the independent measurements from Di Gesu et al (2015), except for the much larger value of ξ 1 found here with respect to Paper 0 and Paper IV, who found a log ξ 1 = −1.2 ± 0.08. There are multiple possible reasons for this apparent discrepancy.…”

Section: The Whole 17 Xmm-newton Observations: Variability Of the Mulsupporting

confidence: 78%

“…Another obvious explanation could be the presence of an additional outflowing absorption component, at such a high ionization state to contribute only/mostly with FeXXV (He-α and He-β) and FeXXVI (Ly-α and Ly-β) absorption lines. Alternatively, both these remaining blueshifted absorption features and red-shifted emission features could be signatures of a Fe PCygni type emission and absorption profile originating in an outflowing, highly ionized wind (Dorodnitsyn 2010;Hagino et al 2015;Gardner & Done 2015;Nardini et al 2015). Finally, another possibility for the 6 keV emission line could be a (yet unmodelled) contribution from a weak, and significantly redshifted and broadened reflection component.…”

Section: Additional Emission and Absorption Complexitiesmentioning

confidence: 99%

“…The shadowing effects of this UV BAL and X-ray obscurer on the larger-scale "historical" UV narrow absorption lines and WA are presented in Arav et al (2015; hereafter Paper II). The high energy properties of the source during, and before, the campaign are shown in Ursini et al (2015; hereafter Paper III), while the study of a short-timescale flaring event that happened in September 2013 and which triggered a Chandra LETG observation is addressed in Di Gesu et al (2015; hereafter Paper IV), together with the analysis of the WA short-term variability during this event. The time-averaged soft X-ray linedominated RGS spectrum is presented and modeled in detail in Whewell et al (2015;hereafter Paper V).…”

Section: Introductionmentioning

confidence: 99%

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Anatomy of the AGN in NGC 5548

Cappi

Marco

Ponti

et al. 2016

A&A

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In 2013, we conducted a large multi-wavelength campaign on the archetypical Seyfert 1 galaxy NGC 5548. Unexpectedly, this usually unobscured source appeared strongly absorbed in the soft X-rays during the entire campaign, and signatures of new and strong outflows were present in the almost simultaneous UV HST/COS data. Here we carry out a comprehensive spectral analysis of all available XMM-Newton observations of NGC 5548 (precisely 14 observations from our campaign plus three from the archive, for a total of ∼763 ks) in combination with three simultaneous NuSTAR observations. We obtain a best-fit underlying continuum model composed by i) a weakly varying flat (Γ ∼ 1.5-1.7) power-law component; ii) a constant, cold reflection (FeK + continuum) component; iii) a soft excess, possibly owing to thermal Comptonization; and iv) a constant, ionized scattered emission-line dominated component. Our main findings are that, during the 2013 campaign, the first three of these components appear to be partially covered by a heavy and variable obscurer that is located along the line of sight (LOS), which is consistent with a multilayer of cold and mildly ionized gas. We characterize in detail the short timescale (mostly ∼ks-to-days) spectral variability of this new obscurer, and find it is mostly due to a combination of column density and covering factor variations, on top of intrinsic power-law (flux and slope) variations. In addition, our best-fit spectrum is left with several (but marginal) absorption features at rest-frame energies ∼6.7−6.9 keV and ∼8 keV, as well as a weak broad emission line feature redwards of the 6.4 keV emission line. These could indicate a more complex underlying model, e.g. a P-Cygni-type emission profile if we allow for a large velocity and wide-angle outflow. These findings are consistent with a picture where the obscurer represents the manifestation along the LOS of a multilayer of gas, which is also in multiphase, and which is likely outflowing at high speed, and simultaneously producing heavy obscuration and scattering in the X-rays, as well as broad absorption features in the UV.

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Section: The Whole 17 Xmm-newton Observations: Variability Of the Mulsupporting

confidence: 78%

Section: Additional Emission and Absorption Complexitiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Anatomy of the AGN in NGC 5548

Cappi

Marco

Ponti

et al. 2016

A&A

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“…A turbulence velocity of σ=300 km s −1 was chosen to account for any narrow absorption lines. The ionization parameter of the absorption table was varied between x = log 0 3 -9 to allow for the typical range in ionization seen toward other Seyfert 1s, with prominent warm absorption components (Kaspi et al 2002;Blustin et al 2005;Detmers et al 2011;Reeves et al 2013;Di Gesu et al 2015). The total N H column was recorded for each value of the ionization parameter, in increments of 0.1 in x log space.…”

Section: Is There Any Warm Absorption Toward Ark 120?mentioning

confidence: 99%

A Deep X-Ray View of the Bare Agn Ark 120. I. Revealing the Soft X-Ray Line Emission

Reeves

Porquet

Braito

et al. 2016

ApJ

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The Seyfert 1 galaxy Ark 120 is a prototype example of the so-called class of bare nucleus active galactic nuclei (AGNs), whereby there is no known evidence for the presence of ionized gas along the direct line of sight. Here deep (>400 ks exposure), high-resolution X-ray spectroscopy of Ark 120 is presented from XMM-Newton observations that were carried out in 2014 March, together with simultaneous Chandra/High Energy Transmission Grating exposures. The high-resolution spectra confirmed the lack of intrinsic absorbing gas associated with Ark 120, with the only X-ray absorption present originating from the interstellar medium (ISM) of our own Galaxy, with a possible slight enhancement of the oxygen abundance required with respect to the expected ISM values in the solar neighborhood. However, the presence of several soft X-ray emission lines are revealed for the first time in the XMM-Newton RGS spectrum, associated with the AGN and arising from the He-and H-like ions of N, O, Ne, and Mg. The He-like line profiles of N, O, and Ne appear velocity broadened, with typical FWHMs of ∼5000 km s −1 , whereas the H-like profiles are unresolved. From the clean measurement of the He-like triplets, we deduce that the broad lines arise from a gas of density n e ∼10 11 cm −3 , while the photoionization calculations infer that the emitting gas covers at least 10% of 4π steradian. Thus the broad soft X-ray profiles appear coincident with an X-ray component of the optical-UV broad-line region on sub-parsec scales, whereas the narrow profiles originate on larger parsec scales, perhaps coincident with the AGN narrow-line region. The observations show that Ark 120 is not intrinsically bare and substantial X-ray-emitting gas exists out of our direct line of sight toward this AGN.

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“…The properties of this obscuring outflow are consistent with those of a disc wind (Kaastra et al 2014). The detailed description of the campaign is given by Mehdipour et al (2015), while the physical and temporal properties of the outflows are described in Arav et al (2015) and Di Gesu et al (2015 INTEGRAL data from the campaign, Ursini et al (2015) studied the broad-band (0.3-400 keV) X-ray spectrum of NGC 5548. A high-energy cut-off of 70 +40 −10 keV, attributed to thermal Comptonization, is found in one observation out of seven, while a lower limit ranging from 50 to 250 keV is found in the other six observations.…”

Section: Introductionmentioning

confidence: 99%

High‐energy monitoring of Seyfert galaxies: The case of NGC 4593

et al. 2016

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We discuss preliminary results from a joint XMM-Newton and NuSTAR monitoring program on the active galactic nucleus NGC 4593, consisting of 5 × 20 ks observations, spaced by two days, performed in January 2015. The source is found to be variable, both in flux and spectral shape, on time scales as short as a few ks. The spectrum clearly softens when the source brightens. A simple timing analysis suggests the presence of a variable soft excess that correlates with the primary continuum.

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Anatomy of the AGN in NGC 5548

Cited by 38 publications

References 66 publications

Anatomy of the AGN in NGC 5548

Anatomy of the AGN in NGC 5548

A Deep X-Ray View of the Bare Agn Ark 120. I. Revealing the Soft X-Ray Line Emission

High‐energy monitoring of Seyfert galaxies: The case of NGC 4593

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