A detailed spectroscopic study of Tidal Disruption Events

TL;DR

This study provides a comprehensive spectroscopic analysis of 16 Tidal Disruption Events, revealing time lags, line profile variations, and relationships between spectral features, luminosity, and temperature, suggesting viewing angle effects influence observed diversity.

Contribution

First detailed spectroscopic population study of optical/UV TDEs, analyzing line profiles, time lags, and spectral evolution to understand their physical properties and diversity.

Findings

Time lags between optical peaks and Hα luminosity span 7-45 days.

Large discrepancies between light-echo distances and blackbody radii.

Inverse relation between Hα luminosity and temperature for T_BB ≥ 25000 K.

Abstract

Spectroscopically, TDEs are characterized by broad ( 10$^{4}$ km/s) emission lines and show large diversity as well as different line profiles. After carefully and consistently performing a series of data reduction tasks including host galaxy light subtraction, we present here the first detailed, spectroscopic population study of 16 optical/UV TDEs. We report a time lag between the peaks of the optical light-curves and the peak luminosity of H$\alpha$ spanning between 7 - 45 days. If interpreted as light-echoes, these lags correspond to distances of 2 - 12 x 10$^{16}$ cm, one to two orders of magnitudes larger than the estimated blackbody radii (R$_{\rm BB}$) of the same TDEs and we discuss the possible origin of this surprisingly large discrepancy. We also report time lags for the peak luminosity of He I $\lambda$5876 line; smaller than the ones of H$\alpha$ for H TDEs and similar or larger for N III Bowen TDEs. We report that N III Bowen TDEs have lower H$\alpha$ velocity widths compared to the rest of the TDEs in our sample and we also find that a strong X-ray to optical ratio might imply weakening of the line widths. Furthermore, we study the evolution of line luminosities and ratios with respect to their radii (R$_{\rm BB}$) and temperatures (T$_{\rm BB}$). We find a linear relationship between H$\alpha$ luminosity and the R$_{\rm BB}$ and potentially an inverse power-law relation with T$_{\rm BB}$ leading to weaker H$\alpha$ emission for T$_{\rm BB}$ $\geq$ 25000 K. The He II/He I ratio becomes large at the same temperatures possibly pointing to an ionization effect. The He II/H$\alpha$ ratio becomes larger as the photospheric radius recedes, implying a stratified photosphere where Helium lies deeper than Hydrogen. We suggest that the large diversity of the spectroscopic features seen in TDEs along with their X-ray properties, can potentially be attributed to viewing angle effects.