# XMMSL2 J144605.0+685735 : a slow tidal disruption event

**Authors:** R.D. Saxton (1), A.M. Read (2), S. Komossa (3), P. Lira (4), K.D., Alexander (5), I. Steele (6), F. Oca\~na (7), E. Berger (8), and P. Blanchard, (8) ((1) ESAC, Spain, (2) Dept. of Physics, Astronomy, University of, Leicester, (3) Max Planck Institut f\"ur Radioastronomie, Bonn, (4), Universidad de Chile, Observatorio Astronomico Nacional Cerro Calan, (5), Center for Interdisciplinary Exploration, Research in Astrophysics (CIERA), and Department of Physics, Astronomy, Northwestern University, (6), Liverpool John Moores University, (7) Dpto. de F{\i}sica de la Tierra y, Astrof{\i}sica, Universidad Complutense de Madrid, (8) Harvard-Smithsonian, Center for Astrophysics)

arXiv: 1908.01065 · 2019-10-02

## TL;DR

This paper reports the discovery and detailed multi-wavelength monitoring of a slow tidal disruption event in a quiescent galaxy, revealing unique evolution patterns and challenging existing models of emission mechanisms.

## Contribution

It presents the first detailed case study of a slow TDE with multi-wavelength data, proposing a new model involving a truncated accretion disk and Compton upscattering.

## Key findings

- X-ray flux increased 20-fold then declined over 600 days.
- UV flux remained stable for 400 days before fading.
- No radio emission detected, constraining jet energy.

## Abstract

Aims. We investigate the evolution of X-ray selected tidal disruption events. Methods. New events are found in near-real time data from XMM-Newton slews and are monitored by multi-wavelength facilities. Results. In August 2016, X-ray emission was detected from the galaxy XMMSL2 J144605.0+685735 (a.k.a. 2MASX 14460522+6857311), a factor 20 times higher than an upper limit from 25 years earlier. The X-ray flux was flat for ~100 days and then fell by a factor 100 over the following 500 days. The UV flux was stable for the first 400 days before fading by a magnitude, while the optical (U,B,V bands) have been roughly constant for 850 days. Optically, the galaxy appears to be quiescent, at a distance of $127\pm{4}$ Mpc (z=$0.029\pm{0.001}$) with a spectrum consisting of a young stellar population of age 1-5 Gyr, an older population and a total stellar mass of ~6 x $10^{9}$ solar masses. The bolometric luminosity peaked at L bol ~ $10^{43}$ ergs s$^{-1}$ with an X-ray spectrum that may be modeled by a power-law of $\Gamma$~2.6 or Comptonisation of a low-temperature thermal component by thermal electrons. We consider a tidal disruption event to be the most likely cause of the flare. Radio emission was absent in this event down to < 10$\mu$Jy, which limits the total energy of a hypothetical off-axis jet to E < 5 x $10^{50}$ ergs. The independent behaviour of the optical, UV and X-ray light curves challenges models where the UV emission is produced by reprocessing of thermal nuclear emission or by stream-stream collisions. We suggest that the observed UV emission may have been produced from a truncated accretion disk and the X-rays from Compton upscattering of these disk photons.

## Full text

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## Figures

19 figures with captions in the complete paper: https://tomesphere.com/paper/1908.01065/full.md

## References

106 references — full list in the complete paper: https://tomesphere.com/paper/1908.01065/full.md

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Source: https://tomesphere.com/paper/1908.01065