The flaring X-ray corona in the quasar PDS 456

TL;DR

This study presents detailed X-ray observations of the quasar PDS 456, revealing a significant flare originating from its corona, with insights into its size, temperature, and spectral behavior, challenging existing models of AGN coronae.

Contribution

First detailed analysis of a bright X-ray flare in PDS 456, providing constraints on coronal size, temperature, and spectral evolution during the flare.

Findings

Coronal size estimated at about 30 gravitational radii.

Coronal temperature measured at 13 keV, among the coolest in AGN.

Flare caused by corona, with no optical/UV variability observed.

Abstract

New Swift monitoring observations of the variable, radio-quiet quasar, PDS 456, are presented. A bright X-ray flare was captured in September 2018, the flux increasing by a factor of 4 and with a doubling time-scale of 2 days. From the light crossing argument, the coronal size is inferred to be about 30 gravitational radii for a black hole mass of $10^{9} {\rm M}_{\odot}$ and the total flare energy exceeds $10^{51}$ erg. A hardening of the X-ray emission accompanied the flare, with the photon index decreasing from $\Gamma=2.2$ to $\Gamma=1.7$ and back again. The flare is produced in the X-ray corona, the lack of any optical or UV variability being consistent with a constant accretion rate. Simultaneous XMM-Newton and NuSTAR observations were performed, $1-3$ days after the flare peak and during the decline phase. These caught PDS 456 in a bright, bare state, where no disc wind absorption features are apparent. The hard X-ray spectrum shows a high energy roll-over, with an e-folding energy of $E_{\rm fold}=51^{+11}_{-8}$ keV. The deduced coronal temperature, of $kT=13$ keV, is one of the coolest measured in any AGN and PDS 456 lies well below the predicted pair annihilation line in X-ray corona. The spectral variability, becoming softer when fainter following the flare, is consistent with models of cooling X-ray coronae. Alternatively, an increase in a non-thermal component could contribute towards the hard X-ray flare spectrum.