7 research outputs found
Using principal component analysis to understand the variability of PDS 456
We present a spectral-variability analysis of the low-redshift quasar PDS 456
using principal component analysis. In the XMM-Newton data, we find a strong
peak in the first principal component at the energy of the Fe absorption line
from the highly blueshifted outflow. This indicates that the absorption feature
is more variable than the continuum, and that it is responding to the
continuum. We find qualitatively different behaviour in the Suzaku data, which
is dominated by changes in the column density of neutral absorption. In this
case, we find no evidence of the absorption produced by the highly ionized gas
being correlated with this variability. Additionally, we perform simulations of
the source variability, and demonstrate that PCA can trivially distinguish
between outflow variability correlated, anti-correlated, and un-correlated with
the continuum flux. Here, the observed anti-correlation between the absorption
line equivalent width and the continuum flux may be due to the ionization of
the wind responding to the continuum. Finally, we compare our results with
those found in the narrow-line Seyfert 1 IRAS 13224-3809. We find that the Fe K
UFO feature is sharper and more prominent in PDS 456, but that it lacks the
lower energy features from lighter elements found in IRAS 13224-3809,
presumably due to differences in ionization
A New Relativistic Component of the Accretion Disk Wind in PDS 456
Past X-ray observations of the nearby luminous quasar PDS 456 (at z = 0.184) have revealed a wide angle accretion disk wind, with an outflow velocity of ∼−0.25 c . Here, we unveil a new, relativistic component of the wind through hard X-ray observations with NuSTAR and XMM-Newton , obtained in 2017 March when the quasar was in a low-flux state. This very fast wind component, with an outflow velocity of −0.46 ± 0.02 c , is detected in the iron K band, in addition to the −0.25 c wind zone. The relativistic component may arise from the innermost disk wind, launched from close to the black hole at a radius of ∼10 gravitational radii. The opacity of the fast wind also increases during a possible obscuration event lasting for 50 ks. We suggest that the very fast wind may only be apparent during the lowest X-ray flux states of PDS 456, becoming overly ionized as the luminosity increases. Overall, the total wind power may even approach the Eddington value
Evidence for a radiatively driven disc-wind in PDS 456?
We present a newly discovered correlation between the wind outflow velocity and the X-ray luminosity in the luminous () nearby () quasar PDS\,456. All the contemporary XMM-Newton, NuSTAR and Suzaku observations from 2001--2014 were revisited and we find that the centroid energy of the blueshifted Fe\,K absorption profile increases with luminosity. This translates into a correlation between the wind outflow velocity and the hard X-ray luminosity (between 7--30\,keV) where we find that where . We also show that this is consistent with a wind that is predominately radiatively driven, possibly resulting from the high Eddington ratio of PDS\,456
Unveiling Sub-pc Supermassive Black Hole Binary Candidates in Active Galactic Nuclei
The elusive supermassive black hole binaries (SMBHBs) are thought to be the penultimate stage of galaxy mergers, preceding a final coalescence phase. SMBHBs are sources of continuous gravitational waves, possibly detectable by pulsar timing arrays; the identification of candidates could help in performing targeted gravitational wave searches. Due to SMBHBs’ origin in the innermost parts of active galactic nuclei (AGN), X-rays are a promising tool for unveiling their presence, by means of either double Fe Kα emission lines or periodicity in their light curve. Here we report on a new method for selecting SMBHBs by means of the presence of a periodic signal in their Swift Burst Alert Telescope (BAT) 105 month light curves. Our technique is based on Fisher’s exact g-test and takes into account the possible presence of colored noise. Among the 553 AGN selected for our investigation, only the Seyfert 1.5 galaxy Mrk 915 emerges as a candidate SMBHB; from subsequent analysis of its light curve we find a period P0 = 35 ± 2 months, and the null hypothesis is rejected at the 3.7σ confidence level. We also present a detailed analysis of the BAT light curve of the only previously X-ray-selected binary candidate source in the literature, the Seyfert 2 galaxy MCG+11-11-032. We find P0 = 26.3 ± 0.6 months, consistent with the one inferred from previously reported double Fe Kα emission lines
A broadband X-ray view of the NLSy1 1E 0754.6+392.8
The soft X-ray band of many active galactic nuclei (AGNs) is affected by obscuration due to partially ionised matter crossing our line of sight. In this context, two past XMM-Newton observations (6 months apart) and a simultaneous NuSTAR-Swift (8 years later) exposure of the Narrow Line Seyfert 1 galaxy 1E 0754.6+392.8 revealed an intense and variable WA and hints of additional absorbers in the Fe K band. We present the first X-ray characterisation of this AGN discussing its broadband (0.3-79 keV) spectrum and temporal properties. We conduct a temporal and spectroscopic analysis on two 10 ks (net exposure) XMM-Newton snapshots performed in April and October 2006. We also study the high energy behaviour of 1E 0754.6+392.8 modelling its broadband spectrum using simultaneous Swift-NuSTAR data. Both phenomenological and physically motivated models are tested. We find the presence of flux variability (150% and 30% for 0.3-2 and 2-10 keV bands, respectively) and spectral changes at months timescales (0.4). A reflection component that is consistent with being constant over years and arising from relatively cold material far from the central super massive black hole is detected. The main spectral feature shaping the 1E 0754.6+392.8 spectrum is a warm absorber. Such a component is persistent over the years and variability of its ionisation and column density is observed down on months in the ranges 3 N and 1.5 2.1. Despite the short exposures, we find possible evidence of two additional highly ionised and high-velocity outflow components in absorption. Longer exposures are mandatory in order to characterise the complex outflow in this AGN