A Star’s Death by a Thousand Cuts: The Runaway Stellar Destruction of AT2023uqm

https://is1-ssl.mzstatic.com/image/thumb/Podcasts211/v4/85/83/c3/8583c308-ba92-864c-4c06-beae89e4ab6c/mza_9538994040864923453.jpg/600x600bb.jpg

Multi-messenger astrophysics

Astro-COLIBRI

64 episodes

1 week ago

Discussions around tools and discoveries in the novel domain of multi-messenger and time domain astrophysics. We'll highlight recent publications, discuss tools to faciliate observations and generally talk about the cool science behind the most violent explosions in the universe.

Astronomy

Science

RSS

All content for Multi-messenger astrophysics is the property of Astro-COLIBRI and is served directly from their servers with no modification, redirects, or rehosting. The podcast is not affiliated with or endorsed by Podjoint in any way.

Astronomy

Science

https://d3t3ozftmdmh3i.cloudfront.net/staging/podcast_uploaded_episode/42166290/42166290-1761905129465-c8fbd4cfd7aaf.jpg

A Star’s Death by a Thousand Cuts: The Runaway Stellar Destruction of AT2023uqm

Multi-messenger astrophysics

13 minutes 19 seconds

2 weeks ago

A Star’s Death by a Thousand Cuts: The Runaway Stellar Destruction of AT2023uqm

In this episode, we dive into the fascinating and violent world of galactic centers with the discovery of **AT2023uqm**, a new nuclear transient offering unprecedented insights into stellar consumption by supermassive black holes (SMBHs).

AT2023uqm is only the second confirmed case of a star undergoing **repeated partial tidal disruption events (rpTDEs)**, where a star on a bound, eccentric orbit repeatedly loses its outer layers as it approaches the SMBH.

**What makes AT2023uqm unique?**

Unlike its predecessor, AT2023uqm exhibits a novel behavior: a nearly **exponential, or "runaway," increase in flare energy** across its series of periodic outbursts. This escalating brightness is evidence of the star’s progressive destruction over time.

Key observations include:

* **Periodicity:** The transient displays at least five distinct, periodic optical flares. The adopted period is **526.75 ± 0.87 days** in the observer’s frame.

* **Light Curve Structure:** Each flare displays a **similar double-peaked structure**. This structure requires constraints on the progenitor star, suggesting it is either a low-mass main-sequence star or, potentially, an evolved giant star.

* **Multi-wavelength Data:** Follow-up campaigns across optical/UV, X-ray, and radio bands found the optical/UV emission maintains a nearly constant blackbody temperature around 18,000 K. The spectra revealed intermediate-width Balmer lines and strong Fe II and Bowen fluorescence lines.

AT2023uqm serves as a crucial framework for modeling and understanding the runaway mass loss phenomena in rpTDEs. Due to the estimated mass loss rate, scientists anticipate **only one or two more flares** before the star is completely disrupted. Be ready: the next outburst is predicted to peak (the first peak) around **August 26, 2026** (MJD 61278).

**Reference:**

This episode is based on the article: **"A Star’s Death by a Thousand Cuts: The Runaway Periodic Eruptions of AT2023uqm"** by Yibo Wang et al. (2025).

Acknowledements: Podcast prepared with Google/NotebookLM. Illustration credits: Ralf Crawford (STScI)