# Discovery of an intermediate-luminosity red transient in M51 and its   likely dust-obscured, infrared-variable progenitor

**Authors:** Jacob E. Jencson (1), Scott M. Adams (1), Howard E. Bond (2, 3),, Schuyler D. van Dyk (4), Mansi M. Kasliwal (1), John Bally (5), Nadejda, Blagorodnova (6), Kishalay De (1), Christoffer Fremling (1), Yuhan Yao (1),, Andrew Fruchter (3), David Rubin (3), Cristina Barbarino (7), Jesper, Sollerman (7), Adam A. Miller (8), Erin K. S. Hicks (9), Matthew A. Malkan, (10), Igor Andreoni (1), Eric C. Bellm (11), Robert Buchheim (12), Richard, Dekany (13), Michael Feeney (13), Sara Frederick (14), Avishay Gal-Yam (15),, Robert D. Gehrz (16), Matteo Giomi (17), Matthew J. Graham (1), Wayne Green, (5), David Hale (13), Matthew J. Hankins (1), Mark Hanson (18), George Helou, (4), Anna Y. Q. Ho (1), T. Hung (19), Mario Juri\'c (11), Malhar R. Kendurkar, (20), S. R. Kulkarni (1), Ryan M. Lau (21), Frank J. Masci (4), James D., Neill (1), Kevin Quin (22), Reed L. Riddle (13), Ben Rusholme (4), Forrest, Sims (23), Nathan Smith (24), Roger M. Smith (13), Maayane T. Soumagnac (15),, Yutaro Tachibana (25, 1), Samaporn Tinyanont (1), Richard Walters (13),, Stanley Watson (18), Robert E. Williams (3, 19) ((1) California, Institute of Technology, (2) Pennsylvania State University, (3) Space, Telescope Science Institute, (4) Caltech/IPAC, (5) University of Colorado, Boulder, (6) Radboud University, (7) Stockholm University, (8) Northwestern, University, (9) University of Alaska Anchorage, (10) University of California, Los Angeles, (11) University of Washington, (12) Lost Gold Observatory, (13), Caltech Optical Observatories, (14) University of Maryland, (15) Weizmann, Institute of Science, (16) University of Minnesota, (17), Humboldt-Universit\"at zu Berlin, (18) Stellar Winds Observatory, (19), University of California Santa Cruz, (20) Prince George Astronomical, Observatory, (21) Japan Aerospace Exploration Agency, (22) Northern Virginia, Astronomy Club, (23) Desert Celestial Observatory, (24) University of, Arizona, (25) Tokyo Institute of Technology)

arXiv: 1904.07857 · 2019-07-31

## TL;DR

This paper reports the discovery and analysis of an intermediate-luminosity red transient in M51, providing insights into its progenitor, spectral features, and implications for the origins of similar transients, challenging previous hypotheses.

## Contribution

The study presents the first detailed characterization of M51 OT2019-1, including its progenitor identification, spectral analysis, and implications for understanding ILRTs and their origins.

## Key findings

- Progenitor likely dust-obscured and infrared-variable before outburst.
- Spectral features resemble SN impostors and ILRTs.
- Higher reddening and luminosity during outburst than previous ILRTs.

## Abstract

We present the discovery of an optical transient (OT) in Messier 51, designated M51 OT2019-1 (also ZTF19aadyppr, AT 2019abn, ATLAS19bzl), by the Zwicky Transient Facility (ZTF). The OT rose over 15 days to an observed luminosity of $M_r=-13$ (${\nu}L_{\nu}=9\times10^6~L_{\odot}$), in the luminosity gap between novae and typical supernovae (SNe). Spectra during the outburst show a red continuum, Balmer emission with a velocity width of $\approx400$ km s$^{-1}$, Ca II and [Ca II] emission, and absorption features characteristic of an F-type supergiant. The spectra and multiband light curves are similar to the so-called "SN impostors" and intermediate-luminosity red transients (ILRTs). We directly identify the likely progenitor in archival Spitzer Space Telescope imaging with a $4.5~\mu$m luminosity of $M_{[4.5]}\approx-12.2$ and a $[3.6]-[4.5]$ color redder than 0.74 mag, similar to those of the prototype ILRTs SN 2008S and NGC 300 OT2008-1. Intensive monitoring of M51 with Spitzer further reveals evidence for variability of the progenitor candidate at [4.5] in the years before the OT. The progenitor is not detected in pre-outburst Hubble Space Telescope optical and near-IR images. The optical colors during outburst combined with spectroscopic temperature constraints imply a higher reddening of $E(B-V)\approx0.7$ mag and higher intrinsic luminosity of $M_r\approx-14.9$ (${\nu}L_{\nu}=5.3\times10^7~L_{\odot}$) near peak than seen in previous ILRT candidates. Moreover, the extinction estimate is higher on the rise than on the plateau, suggestive of an extended phase of circumstellar dust destruction. These results, enabled by the early discovery of M51 OT2019-1 and extensive pre-outburst archival coverage, offer new clues about the debated origins of ILRTs and may challenge the hypothesis that they arise from the electron-capture induced collapse of extreme asymptotic giant branch stars.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1904.07857/full.md

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1904.07857/full.md

## References

105 references — full list in the complete paper: https://tomesphere.com/paper/1904.07857/full.md

---
Source: https://tomesphere.com/paper/1904.07857