International Gemini Observatory and SOAR Discover Surprising Link Between Fast X-ray Transients and the Explosive Death of Massive Stars

Gemini North and Gemini South Capture the Fading Light of SN 2025kg. Three panel image shows how the light faded with time. — This sequence of images shows the fading light of the supernova SN 2025kg, which followed the fast X-ray transient EP 250108a, a powerful blast of X-rays that was detected by Einstein Probe (EP) in early 2025. Their analysis reveals that fast X-ray transients can result from the ‘failed’ explosive death of a massive star. Credit: International Gemini Observatory/NOIRLab/NSF/AURA Acknowledgment: PI: J. Rastinejad (Northwestern University) Image processing: J. Miller & M. Rodriguez (International Gemini Observatory/NSF NOIRLab), M. Zamani (NSF NOIRLab)

Using a combination of telescopes, including the International Gemini Observatory, funded in part by the U.S. National Science Foundation and operated by NSF NOIRLab, and the SOAR telescope at Cerro Tololo Inter-American Observatory in Chile, a Program of NSF NOIRLab, astronomers have characterized the closest supernova linked to a fast X-ray transient. The observations reveal that these bright blasts of X-rays may be the result of a ‘failed’ explosive death of a massive star.

Since their first detection, powerful bursts of X-rays from distant galaxies, known as fast X-ray transients (FXTs), have mystified astronomers. FXTs have historically been elusive events, occurring at vast distances away from Earth and only lasting seconds to hours. Einstein Probe (EP), launched in 2024, is dedicated to observing transient events in the X-ray and is changing the game for astronomers looking to understand the origin of these exotic events.

In January 2025 EP alerted astronomers to the nearest FXT known at the time, named EP 250108a. Its proximity to Earth (2.8 billion light-years away) provided an unprecedented opportunity for detailed observations of the event’s evolving behavior.

After the initial detection of EP 250108a, a large, international team of astronomers jumped into action to capture its signal in multiple wavelengths. The FLAMINGOS-2 spectrograph on the Gemini South telescope, one half of the International Gemini Observatory, provided near-infrared data, while the Gemini Multi-Object Spectrograph (GMOS) on the Gemini North telescope provided optical. Gemini’s rapid response capabilities allowed the team to quickly point to the location of EP 250108a where they found the shining aftermath of the explosive death of a massive star, known as a supernova.

Through analysis of EP 250108a’s rapidly evolving signal over the first six days following initial detection, the team found that this FXT is likely a ‘failed’ variation of a gamma-ray burst (GRB). GRBs are the most powerful explosions in the Universe and have been observed preceding supernovae. During these events, violent geysers of high-energy particles burst through a star’s outer layers as it collapses in on itself. These jets flow at nearly the speed of light and are detectable by their gamma-ray emission.

EP 250108a appears similar to a jet-driven explosion, but one in which the jets do not break through the outer layers of the dying star and instead remain trapped inside. As the stifled jets interact with the star’s outer layers, they decelerate and their kinetic energy is converted to the X-rays detected by Einstein Probe.

“This FXT supernova is nearly a twin of past supernovae that followed GRBs,” says Rob Eyles-Ferris, a postdoctoral researcher at the University of Leicester and lead author of one of two companion paperspresenting these results, to appear in The Astrophysical Journal Letters. “Our observations of the early stages of EP 250108a’s evolution show that the explosions of massive stars can produce both phenomena.”

While these early-stage observations provide insight into the mechanisms driving the FXT, longer-term monitoring of the event is necessary to piece together the characteristics of the progenitor star. So the team continued observing EP 250108a beyond the first six days, watching as the emission from the trapped jet faded and the optical signal from its associated supernova, SN 2025kg, dominated the spectra.

“The X-ray data alone cannot tell us what phenomena created the FXT,” says Jillian Rastinejad, PhD student at Northwestern University and lead author of the second companion paper. “Our optical monitoring campaign of EP 250108a was key to identifying the aftermath of the FXT and assembling the clues to its origin.”

At the location of EP 250108a, the team observed a rise in optical brightness that lasted a few weeks before fading, along with spectra containing broad absorption lines. These characteristics indicate that the FXT is associated with a Type Ic broad-lined supernova.

Near-infrared observations from the 4.1-meter Southern Astrophysical Research (SOAR) Telescope at NSF Cerro Tololo Inter-American Observatory (CTIO) in Chile further helped to constrain the supernova’s peak brightness, offering more clues as to what the progenitor star looked like. The team estimates that the star whose death ignited EP 250108a and its associated supernova had a mass of about 15–30 times that of the Sun.

“Our analysis shows definitively that FXTs can originate from the explosive death of a massive star,” says Rastinejad. “It also supports a causal link between GRB-supernovae and FXT-supernovae, in which GRBs are produced by successful jets and FXTs are produced by trapped or weak jets.”

Together, the team’s companion papers present the most detailed dataset to date of a supernova accompanying an EP FXT. Their combined analysis indicates that ‘failed’ jets associated with FXTs are more common in massive star explosions than ‘successful’ jets associated with GRBs. Since the launch of EP, FXTs have been detected several times each month. Meanwhile, detections of GRBs linked to supernovae have historically been sparse, occurring roughly once per year.