Comparison of X-ray Emission Properties of TDEs and Soft Flares from AGNs

Abstract

X-ray flaring activity from active galactic nuclei (AGNs) may mimic the expected emission from tidal disruption events (TDEs), thus contaminating TDE searches. To compare X-ray emission properties between TDEs and AGNs, we cross-match publicly available XMM-Newton and Swift-XRT point source catalogs with the Million Quasars Catalog and optically selected TDEs. We find that AGNs tend to become softer with a similar hardness ratio (HR) value as TDEs during their flaring events. The soft HRs during flaring events in these AGNs are driven by the emergence of a blackbody-like component below 2 keV, likely associated with the soft X-ray excess, as well as the continuum emission becoming steeper with the increase of accretion rate. We find 2.5% in XMM-Newton (23 out of 920) and 4.4% in Swift-XRT (179 out of 4089) AGNs display flares with peak count rate >2σ from the median count rate and peak HR<-0.75. The rate of such flares in XMM-Newton and Swift-XRT is (1.1-2.5)×10-3\ galaxy-1\ yr-1 and (0.9-2.0)×10-3\ galaxy-1\ yr-1, respectively. We also estimate the rate of flares with a maximum flux change (peak/min) of >20× over on a rest-frame time scale of two years or more with a HR<-0.75 at peak to be (4.7-11.0)×10-5\ galaxy-1\ yr-1 and (3.1-7.1)×10-5\ galaxy-1\ yr-1 in XMM-Newton and Swift-XRT, respectively. Finding an optical or infrared counterpart may help to identify these flaring AGNs. We confirm 61% and 79% of flaring sources from XMM-Newton and Swift-XRT, respectively, as AGNs through variability in ZTF light curves or a WISE W1-W2>0.8 mag color cut.