Compact Accretion Disks in the Aftermath of Tidal Disruption Events: Parameter Inference from Joint X-ray Spectra and UV/Optical Photometry Fitting
Abstract
We present a multi-wavelength analysis of 14 tidal disruption events (TDEs)-including an off-nuclear event associated with an ultra-compact dwarf galaxy-selected for having available thermal X-ray spectra during their late-time UV/optical plateau phase. We show that at these stages, the full spectral energy distribution - X-ray spectra and UV/optical photometry - is well described by a compact, yet standard accretion disk, the same disk which powers the X-rays at all times. By fitting up to three epochs per source with a fully relativistic disk model, we show that many system properties can be reliably recovered, including importantly the black hole mass (M). These accretion-based M values, which in this sample span nearly three orders of magnitude, are consistent with galactic scaling relations but are significantly more precise (68\% credible interval < 0.3 dex) and physically motivated. Expected accretion scaling relations (e.g., LBol disk / LEdd Tp4 M-1), TDE-specific physics correlations (Lplat M2/3 and Rout/rg M-2/3) and black hole-host galaxy correlations (M-Mgal and M-σ) naturally emerge from the data and, for the first time, are self-consistently extended into the intermediate-mass (IMBH, M < 105) regime. We discuss the implications of these results for TDE physics and modeling. We also review and discuss different methods for M inference in TDEs, and find that approaches based on physical models of the early-time UV/optical emission are not able to recover (at a statistically significant level) black hole-host galaxy scalings.
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