Resolving the X-ray obscuration in a low flux observation of the quasar PDS 456

TL;DR

This study presents simultaneous multi-wavelength observations of quasar PDS 456, revealing complex, inhomogeneous X-ray absorption and outflows, with minimal UV absorption, indicating a highly ionized, dynamic wind environment.

Contribution

First simultaneous X-ray and UV observations of PDS 456 during low flux state, revealing detailed properties of the inhomogeneous wind and obscuration mechanisms.

Findings

Detected highly absorbed, broad-band X-ray spectrum with soft and iron K outflows.

Observed increased obscuration during X-ray dip, suggesting an eclipse.

Found minimal UV absorption, indicating high ionization of the wind.

Abstract

Simultaneous XMM-Newton, NuSTAR and HST observations, performed in March 2017, of the nearby ($z=0.184$) luminous quasar PDS 456 are presented. PDS 456 had a low X-ray flux compared to past observations, where the first of the two new XMM-Newton observations occurred during a pronounced dip in the X-ray lightcurve. The broad-band X-ray spectrum is highly absorbed, attenuated by a soft X-ray absorber of column density $N_{\rm H}=6\times10^{22}$ cm$^{-2}$. An increase in obscuration occurs during the dip, which may be due to an X-ray eclipse. In addition, the persistent, fast Fe K outflow is present, with velocity components of $-0.25c$ and $-0.4c$. The soft absorber is less ionized ($\log\xi=3$) compared to the iron K outflow ($\log\xi=5$) and is outflowing with a velocity of approximately $-0.2c$. A soft X-ray excess is present below 1 keV against the highly absorbed continuum and can be attributed to the re-emission from a wide angle wind. The complex X-ray absorption present in PDS 456 suggests that the wind is inhomogeneous, whereby the soft X-ray absorber originates from denser clumps or filaments which may form further out along the outflow. In contrast to the X-ray observations, the simultaneous UV spectrum of PDS 456 is largely unabsorbed, where only a very weak broad absorption trough is present bluewards of Ly$\alpha$, compared to a past observation in 2000 when the trough was significantly stronger. The relative weakness of the UV absorption may be due to the soft X-ray absorber being too highly ionized and almost transparent in the UV band.