AT2024lhc and AT2024kmq in the landscape of featureless tidal disruption events

Abstract

We study AT2024kmq and AT2024lhc, two tidal disruption events (TDEs) with blue featureless spectra associated with high-mass black holes (M BH 108\,M). Both events show optical precursors consistent with shock dissipation from stream self-intersection. Their X-ray emission is luminous (L X 1044\, erg\,s-1), highly variable (with minimum observed variability timescales of 1.3\,hr and 4.8\,hr for factor of 3 flux changes), long-lasting (>1\, yr), emerging no later than the optical peak, and well characterized by power-laws with 1.7<Γ<3 (where fν ν1-Γ). The X-ray properties and radio non-detections support a compact corona ( 10 r g) producing Comptonized X-ray emission. Using all published featureless TDEs, we find statistically significant bimodality in the distribution of their peak UV/optical blackbody luminosities and radii. We assemble a comparison TDE sample with early-time X-ray observations with eROSITA, in which we find different M BH distributions in TDEs with different X-ray spectral evolution properties: low-mass black holes (M BH 106 M) remain soft (Γ>4) within t 2\,yr, intermediate masses ( 107 M) transition from soft to hard at 1 yr, while high masses ( 108 M) are hard (1.5<Γ 3) from the outset. We interpret this result as evidence that the soft-to-hard state transition in TDEs occurs at the critical threshold of M acc 0.03 M Edd (similar to X-ray binaries), using the fact that the transition timescale predicted by simple disk theory scales with black hole mass as t tr M BH-3/4.