# On the Diversity of Fallback Rates from Tidal Disruption Events with   Accurate Stellar Structure

**Authors:** Elen C. A. Golightly, C. J. Nixon, Eric R. Coughlin

arXiv: 1907.05895 · 2019-09-25

## TL;DR

This study demonstrates that realistic stellar structures significantly influence the fallback rates in tidal disruption events, affecting the interpretation of SMBH properties from observed lightcurves.

## Contribution

It introduces the use of detailed stellar models from MESA to analyze fallback rates, revealing deviations from simple polytropic models and emphasizing the importance of stellar age and structure.

## Key findings

- Fallback rates differ qualitatively from polytropic models.
- Stellar age impacts fallback curve shape and peak timing.
- Discrepancies in black hole mass estimates can be an order of magnitude.

## Abstract

The tidal disruption of stars by supermassive black holes (SMBHs) can be used to probe the SMBH mass function, the properties of individual stars, and stellar dynamics in galactic nuclei. Upcoming missions will detect thousands of TDEs, and accurate theoretical modeling is required to interpret the data with precision. Here we analyze the influence of more realistic stellar structure on the outcome of TDEs; in particular, we compare the fallback rates -- being the rate at which tidally-disrupted debris returns to the black hole -- from progenitors generated with the stellar evolution code {\sc mesa} to $\gamma = 4/3$ and $\gamma = 5/3$ polytropes. We find that {\sc mesa}-generated density profiles yield qualitatively-different fallback rates as compared to polytropic approximations, and that only the fallback curves from low-mass ($1M_{\odot}$ or less), zero-age main-sequence stars are well fit by either a $\gamma = 4/3$ or $5/3$ polytrope. Stellar age has a strong affect on the shape of the fallback curve, and can produce characteristic timescales (e.g., the time to the peak of the fallback rate) that greatly differ from the polytropic values. We use these differences to assess the degree to which the inferred black hole mass from the observed lightcurve can deviate from the true value, and find that the discrepancy can be at the order of magnitude level. Accurate stellar structure also leads to a substantial variation in the critical impact parameter at which the star is fully disrupted, and can increase the susceptibility of the debris stream to fragmentation under its own self-gravity. These results suggest that detailed modeling is required to accurately interpret observed lightcurves of TDEs.

## Full text

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## Figures

31 figures with captions in the complete paper: https://tomesphere.com/paper/1907.05895/full.md

## References

41 references — full list in the complete paper: https://tomesphere.com/paper/1907.05895/full.md

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Source: https://tomesphere.com/paper/1907.05895