The Wandering Supermassive Black Hole Powering the off-nuclear TDE AT2024tvd

Abstract

We present an analysis of the spectral energy distribution (SED) of the off-nuclear tidal disruption event (TDE) AT2024tvd during its late-time plateau phase, combining X-ray spectra and UV/optical photometry. Using a fully relativistic, compact accretion disk model with self-consistent inner-disk Comptonization, we reproduce the observed SED without significant residuals. The inferred black hole mass log10(M/M) ≈ 6.0 0.2, and the inferred disk parameters place AT2024tvd within known TDE-disk scaling relations (L bol disk/L Edd T p4 M-1, L plat M2/3, R out/r g M-2/3). Our results show that: (i) there is no detected star cluster or dwarf galaxy associated with the source, down to a mass limit of 10(M gal/M) ≤ 7.6; (ii) the black hole is a wandering supermassive, rather than intermediate-mass, black hole; and (iii) the source represents an extreme case of black hole-to-host mass ratio, with M/M gal > 3\%, consistent with a heavily tidally stripped nucleus. The latter aligns with cosmological simulations predicting that surviving host remnants of most wandering black holes should not retain a detectable stellar overdensity when located at small halo-centric distances. We discuss differences with previous analyses of this source and highlight why our modeling approach provides a more physically consistent solution with more reliable parameter inference.