Supersoft, luminous X-ray sources in galactic nuclei

TL;DR

This study develops a spectral feature-based method to identify extragalactic supersoft X-ray sources, successfully discovering new TDE candidates and known sources, advancing the understanding of extreme accretion phenomena in galactic nuclei.

Contribution

It introduces a novel spectral approach for TDE detection, moving beyond variability-based methods, and demonstrates its effectiveness through discovery of new candidates and confirmation of known sources.

Findings

Successfully retrieved known supersoft AGN and TDEs

Discovered four new TDE candidates

Confirmed one candidate as a likely TDE via follow-up

Abstract

Tidal disruption events (TDEs) are usually discovered at X-ray or optical wavelengths through their transient nature. A characteristic spectral feature of X-ray detected TDEs is a "supersoft" X-ray emission, not observed in any other extragalactic source, with the exception of a few, rapidly variable hyper-luminous X-ray sources (HLXs) or supersoft active galactic nuclei (AGN) that are however distinguishable by their optical emission. The goal of our work is to find extragalactic supersoft sources associated with galactic centres. We expect this category to include overlooked TDEs, supersoft AGN and nuclear HLXs. Finding such sources would allow for the study of extreme regime accretion on different black hole mass scales. We searched for supersoft X-ray sources (SSS) by cross-correlating optical and X-ray catalogues to select extragalactic near-nuclear sources and we then filtered for very steep spectra (photon index $\Gamma>3$) and high X-ray luminosities ($L_X>10^{41}$~erg~s$^{-1}$). With our blind search, we retrieved about 60 sources including 15 previously known supersoft AGN or TDEs, so demonstrating the efficiency of our selection. Of the remaining sample, 36 sources, although showing steeper-than-usual spectra, are optically classified as AGN. The remaining nine, previously unknown sources show spectral properties consistent with the emission by extremely soft-excess dominated AGN (five sources) or TDE (four sources). An {\it XMM-Newton} follow-up observation of one of these sources confirmed its likely TDE nature. Our work is the first attempt to discover TDEs by their spectral features rather than their variability and has been successful in retrieving known TDEs as well as discovering new extreme ultrasoft sources, including four new TDE candidates, one of which is confirmed via follow-up observations.