X-ray imaging of the ionisation cones in NGC 5252

TL;DR

This study uses X-ray observations from XMM-Newton and Chandra to analyze the ionisation cones in NGC 5252, revealing the physical conditions of the gas and the nature of the central AGN, suggesting a quasar relic with steady accretion.

Contribution

It combines high-resolution X-ray and optical data to characterize the ionized gas and the nuclear source in NGC 5252, proposing a new scenario for its AGN activity history.

Findings

Soft X-ray emission overlaps with [OIII] optical images.

Nuclear spectrum indicates a flat, absorbed X-ray source.

Electron density follows an r$^{-2}$ law, consistent with constant ionization parameter.

Abstract

The physical conditions of the gas forming the narrow line regions (NLR) in active galactic nuclei (AGN) have been extensively studied in the optical band. We take advantage of the spectacular extension ($\sim$15") of the NLR in the type II Seyfert galaxy NGC 5252 and of the complementary characteristics of $XMM$--$Newton$ and $Chandra$ to investigate the physical conditions of the gas in this galaxy. The X-ray data from $XMM$--$Newton$ are used to define the spectral properties of the ionising nuclear source. The $Chandra$ data are used to trace the spatial characteristics of the soft X-ray emission. This information is then compared to the HST characteristics. The X-ray spectrum of the nucleus of NGC 5252 is intrinsically flat and absorbed by neutral gas with a column density N~10$^{22}$ cm$^{-2}$. Below 1 keV a soft excess is detected. The high-resolution spectrum obtained with the XMM-Newton RGS shows the presence, in the 0.2-1.5 keV range, of emission lines which strongly indicate that the soft X-ray component is due to ionised gas. Moreover, the soft X-ray emission is spatially resolved around and well overlaps the images obtained in narrow [OIII] optical band. The [OIII]/soft-X flux ratios along the ionisation cones is basically constant. This indicates that the electron density does not significantly deviates from the r$^{-2}$ law (constant ionisation parameter). This result combined with previous optical studies suggest two plausible but different scenarios in the reconstruction of the last 30000 years history of the central AGN. The most promising one is that the source is indeed a "quasar relic" with steady and inefficient energy release from the accretion of matter onto the central super-massive black-hole. This scenario is suggested also by the flat nuclear X-ray spectrum that suggests an advection dominate accretion flow (ADAF) like emission mechanism.