UV and Optical Signatures of Late-time Disk Instabilities in Tidal Disruption Events

TL;DR

This paper models UV and optical signatures of late-time disk instabilities in TDEs, predicting brief transients detectable by upcoming surveys, and searches for these in existing data to constrain their occurrence.

Contribution

It introduces a model for UV/optical signatures of disk instabilities in TDEs and provides observational constraints from current data.

Findings

Predicted UV-bright transients lasting days with specific luminosities.

Estimated detectability of these transients by future surveys.

Placed upper limits on flare rates in existing TDEs.

Abstract

Tidal disruption events (TDEs) are unique probes of evolving accretion in supermassive black holes. Recent models of TDE disks show that they undergo brief thermal instabilities with temporal super-Eddington accretion at late times, which has been suggested as a possibility to explain the ubiquitous late radio emergence in TDEs. We model the ultraviolet (UV) and optical signatures of such disk instabilities, expected from the accretion power being reprocessed by the optically-thick outflow following super-Eddington accretion. Our model predicts brief UV-bright transients lasting for days, with luminosities of $10^{42}$-$10^{43}$ erg s$^{-1}$ in near-UV and $10^{41}$-$10^{42}$ erg s$^{-1}$ in optical for a typical TDE by a $10^6~M_\odot$ black hole. These could be detectable by near-future surveys such as ULTRASAT, Vera C. Rubin Observatory and Argus Array, for TDEs of redshifts out to $\approx 0.1$. We further conduct a search for these transients in existing nearby TDEs using data from the Zwicky Transient Facility, placing upper limits on the flare rate for each TDE of $1$-$2$ yr$^{-1}$ dependent on the outflow mass. In the era of future surveys, combined UV/optical and radio monitoring would be an important test to the disk instability phenomena, as well as its explanation for the late-time radio emission in TDEs.