Systematic light curve modelling of TDEs: statistical differences between the spectroscopic classes

TL;DR

This study models light curves of 32 TDEs to identify statistical differences between spectroscopic classes, revealing variations in disruption completeness, photosphere extension, and possible accretion mechanisms related to black hole mass.

Contribution

It provides the first systematic light curve modeling comparison across TDE spectroscopic classes, linking physical disruption properties to spectral features.

Findings

TDE-H events originate from less complete disruptions.

TDE-H events have more extended photospheres.

Black hole mass correlates linearly with radiative efficiency.

Abstract

With the sample of observed tidal disruption events (TDEs) now reaching several tens, distinct spectroscopic classes have emerged: TDEs with only hydrogen lines (TDE-H), only helium lines (TDE-He), or hydrogen in combination with He II and often N III/O III (TDE-H+He). Here we model the light curves of 32 optically-bright TDEs using the Modular Open Source Fitter for Transients (MOSFiT) to estimate physical and orbital properties, and look for statistical differences between the spectroscopic classes. For all types, we find a shallow distribution of star masses, compared to a typical initial mass function, between $\sim 0.1-1$ M$_\odot$, and no TDEs with very deep ($\beta \gg 1$) encounters. Our main result is that TDE-H events appear to come from less complete disruptions (and possibly lower SMBH masses) than TDE-H+He, with TDE-He events fully disrupted. We also find that TDE-H events have more extended photospheres, in agreement with recent literature, and argue that this could be a consequence of differences in the self-intersection radii of the debris streams. Finally, we identify an approximately linear correlation between black hole mass and radiative efficiency. We suggest that TDE-H may be powered by collision-induced outflows at relatively large radii, while TDE-H+He could result from prompt accretion disks, formed more efficiently in closer encounters around more massive SMBHs.