The X-ray through Optical Fluxes and Line Strengths of Tidal Disruption Events

TL;DR

This paper models the spectral energy distribution and line strengths of tidal disruption events, explaining optical and X-ray observations through radiative transfer in an extended stellar debris envelope.

Contribution

It provides an analytical and numerical framework for understanding how extended envelopes reprocess radiation in TDEs, accounting for spectral features and flux variations.

Findings

Extended envelopes can produce observed optical fluxes of ~10^43 erg/s.

High accretion luminosities allow X-rays to escape and be observed simultaneously.

Hydrogen lines are suppressed relative to helium lines due to optical depth effects.

Abstract

Observations of luminous flares resulting from the possible tidal disruption of stars by supermassive black holes have raised a number of puzzles. Outstanding questions include the origin of the optical and ultraviolet (UV) flux, the weakness of hydrogen lines in the spectrum, and the occasional simultaneous observation of x-rays. Here we study the emission from tidal disruption events (TDEs) produced as radiation from black hole accretion propagates through an extended, optically thick envelope formed from stellar debris. We analytically describe key physics controlling spectrum formation, and present detailed radiative transfer calculations that model the spectral energy distribution (SED) and optical line strengths of TDEs near peak brightness. The steady-state transfer is coupled to a non local thermodynamic equilibrium treatment of the excitation and ionization states of hydrogen, helium and oxygen (as a representative metal). Our calculations show how an extended envelope can reprocess a fraction of soft x-rays and produce the observed optical fluxes of order 10^43 ergs per second. Variations in the mass or size of the envelope may help explain how the optical flux changes over time with roughly constant color. For high enough accretion luminosities, x-rays can highly ionize the reprocessing region and escape to be observed simultaneously with the optical flux, producing an SED not described by a single blackbody. Due to optical depth effects, hydrogen Balmer line emission is often strongly suppressed relative to helium line emission (with HeII-to-H line ratios of at least 5:1 in some cases) even in the disruption of a solar-composition star. We discuss the implications of our results to understanding the type of stars destroyed in TDEs and the physical processes responsible for producing the observed flares.