We present fundamental scaling relationships between properties of the
optical/UV light curves of tidal disruption events (TDEs) and the mass of the
black hole that disrupted the star. We have uncovered these relations from the
late-time emission of TDEs. Using a sample of 63 optically-selected TDEs, the
latest catalog to date, we observed flattening of the early-time emission into
a near-constant late-time plateau for at least two-thirds of our sources.
Compared to other properties of the TDE lightcurves (e.g., peak luminosity or
decay rate) the plateau luminosity shows the tightest correlation with the
total mass of host galaxy (p-value of 2Γ10β6, with a residual
scatter of 0.3 dex). Physically this plateau stems from the presence of an
accretion flow. We demonstrate theoretically and numerically that the amplitude
of this plateau emission is strongly correlated with black hole mass. By
simulating a large population of TDEs, we determine a plateau luminosity-black
hole mass scaling relationship well described by log10β(Mββ/Mββ)=1.50log10β(Lplatβ/1043ergsβ1)+9.0. The observed plateau
luminosities of TDEs and black hole masses in our large sample are in excellent
agreement with this simulation. Using the black hole mass predicted from the
observed TDE plateau luminosity, we reproduce the well-known scaling relations
between black hole mass and galaxy velocity dispersion. The large black hole
masses of 10 of the TDEs in our sample allow us to provide constraints on their
black hole spins, favouring rapidly rotating black holes. We add 49 (34) black
hole masses to the galaxy mass (velocity dispersion) scaling relationships,
updating and extending these correlations into the low black hole mass regime.Comment: 24 pages + appendices, 20 figures. Submitted to MNRAS, comments
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