# The Masses of Supernova Remnant Progenitors in M83

**Authors:** Benjamin F. Williams, Tristan J. Hillis, William P. Blair, Knox S., Long, Jeremiah W. Murphy, Andrew Dolphin, Rubab Khan, Julianne J. Dalcanton

arXiv: 1904.10490 · 2019-08-21

## TL;DR

This study uses Hubble Space Telescope data to analyze the ages and progenitor masses of supernova remnants in M83, revealing a steep progenitor mass distribution and identifying the highest-mass progenitors to date.

## Contribution

It provides the largest collection of high-mass supernova progenitors and constrains the progenitor mass distribution in M83 using resolved stellar populations.

## Key findings

- 47 SNRs with progenitor masses >15 M⊙
- Steeper progenitor mass distribution than Salpeter IMF
- Highest-mass progenitor inferred with <8 Myr age constraint

## Abstract

We determine the ages of the young, resolved stellar populations at the locations of 237 optically-identified supernova remnants in M83. These age distributions put constraints on the progenitor masses of the supernovae that produced 199 of the remnants. The other 38 show no evidence for having a young progenitor and are therefore good Type Ia SNR candidates. Starting from Hubble Space Telescope broadband imaging, we measured resolved stellar photometry of seven archival WFC3/UVIS fields in F336W, F438W, and F814W. We generate color-magnitude diagrams of the stars within 50 pc of each SNR and fit them with stellar evolution models to obtain the population ages. From these ages we infer the progenitor mass that corresponds to the lifetime of the most prominent age that is $<$50 Myr. In this sample, there are 47 SNRs with best-fit progenitor masses $>$15 M$_{\odot}$, and 5 of these are $>$15 M$_{\odot}$ at 84% confidence. This is the largest collection of high-mass progenitors to date, including our highest-mass progenitor inference found so far, with a constraint of $<$8 Myr. Overall, the distribution of progenitor masses has a power-law index of $-3.0^{+0.2}_{-0.7}$, steeper than Salpeter initial mass function ($-2.35$). It remains unclear whether the reason for the low number of high-mass progenitors is due to the difficulty of finding and measuring such objects or because only a fraction of very massive stars produce supernovae.

## Full text

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## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1904.10490/full.md

## References

70 references — full list in the complete paper: https://tomesphere.com/paper/1904.10490/full.md

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Source: https://tomesphere.com/paper/1904.10490