A mysterious 10-second flash from deep space has shattered records and stunned scientists. Detected by a new satellite and confirmed by the James Webb Telescope, this ancient explosion is forcing experts to rethink what they thought they knew about the early universe.
A brilliant cosmic flash, brief yet immensely powerful,
travelled over 13 billion years before reaching Earth. It passed through a
universe that was still young, turbulent and dark, long before galaxies like
our own had taken shape. The burst was only ten seconds long.
Its origin was not immediately clear. But as data
accumulated from space- and ground-based telescopes, scientists realised they
were observing something far older than anything previously confirmed in its
class. A collapsing star, perhaps. Or a type of stellar death not yet fully
understood.
Signals like this are not uncommon. They are detected,
catalogued and studied. Yet this one stood apart. The time it took to arrive,
and the way it unfolded, made it different.
By the time its nature was confirmed, it had broken a
record. The light came from a supernova that exploded when the cosmos was just
730 million years old. Not only is it the most distant event of its kind ever
observed, it may also reshape how researchers think about star formation in the
universe’s first billion years.
A Coordinated International Detection
The initial detection occurred on 14 March 2025, when the
SVOM (Space-based multi-band astronomical Variable Objects Monitor) satellite,
a joint French-Chinese mission, recorded a gamma-ray burst lasting ten seconds.
These long bursts are commonly associated with the death of massive stars and
the birth of black holes, emitting focused jets of energy that remain visible
across vast cosmic distances.
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Artist’s rendering of the SVOM (Space-based multi-band
astronomical Variable Objects Monitor) satellite. Credit: CNES |
SVOM’s early success in identifying what was later
designated GRB 250314A was notable, as the mission had only recently begun full
operations. Researchers from the Observatoire de Paris – PSL and other European
institutions confirmed that the burst originated during the Epoch of
Reionisation, the era when the first stars and galaxies began ionising the
intergalactic medium.
Within hours of detection, NASA’s Neil Gehrels Swift
Observatory pinpointed the gamma-ray source. Follow-up observations by the
Nordic Optical Telescope and Very Large Telescope (VLT) revealed an infrared
afterglow, allowing astronomers to determine a redshift of 7.3, indicating the
light had travelled more than 13 billion years.
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The source of a super bright flash of light known as a
gamma-ray burst: a supernova that exploded when the Universe was only 730
million years old. Credit: NASA, ESA, CSA, STScI, A. Levan (IMAPP), Image
Processing: A. Pagan (STScI) |
Few gamma-ray bursts have ever been detected from this early
in cosmic history. According to the ESA’s mission update, this particular event
now holds the record for the most distant supernova confirmed to date.
Confirmation by the James Webb Space Telescope
Three and a half months after the initial burst, the James
Webb Space Telescope (JWST) was directed toward the fading afterglow. This
delay was not a setback. Because of the expansion of the universe, light from
distant objects becomes stretched, a phenomenon known as redshift, and events
appear to unfold over longer periods of time.
JWST’s NIRCam and NIRSpec instruments captured images of
both the supernova and its host galaxy, confirming that the gamma-ray burst
originated from the collapse of a massive star. This marks the first time a
host galaxy has been detected for a supernova so distant in both space and
time.
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This two-part illustration represents supernova GRB 250314A
as it was exploding and three months after that when Webb observed it. Webb
confirmed the supernova occurred when the Universe was only 730 million years
old. Credit: NASA, ESA, CSA, STScI, L. Hustak (STScI) |
In a peer-reviewed paper published in Astronomy &
Astrophysics Letters and cited by the European Southern Observatory and NASA,
scientists confirmed that GRB 250314A broke the previous distance record set by
a supernova observed at a redshift of 4.3.
“Only Webb could directly show that this light is from a
supernova, a collapsing massive star,” said Andrew Levan, professor at Radboud
University and lead author of one of the studies.
The team used a rapid-turnaround Director’s Discretionary
Time program to ensure the event was observed at peak brightness. Light from
the explosion had been stretched across time, so capturing the right moment
required precise modelling and timing.
Unexpected Similarity to Modern Supernovae
The results challenged long-standing assumptions. The
explosion did not show the unique chemical or energetic traits expected from
stars in the early universe, often referred to as Population III stars. These
first-generation stars, lacking in heavy elements (or metals), were thought to
die in highly energetic and asymmetric explosions.
Instead, data from JWST observations revealed a standard
Type II supernova, matching closely with those observed in the local universe
today. This suggests that the processes shaping star death, and possibly even
chemical enrichment, were already well underway just 730 million years after
the Big Bang.
Nial Tanvir, professor at the University of Leicester and
co-author of the study, noted: “Webb showed that this supernova looks exactly
like modern supernovae.”
If confirmed across additional events, this could indicate
that galaxies were evolving faster than previously thought, producing multiple
generations of stars in a relatively short cosmological time span.
Implications for Early Cosmic Evolution
The detection of GRB 250314A provides new insight into how
quickly complexity emerged in the early universe. With the combined efforts of
SVOM, JWST, and other ground-based facilities, researchers were able to confirm
both the nature of the explosion and the structure of its host environment.
The discovery also illustrates how gamma-ray bursts can
serve as powerful tools for probing the universe’s earliest epochs. Their
brightness and distinct signatures allow scientists to trace cosmic events
occurring billions of years ago, offering a complementary approach to
traditional deep-field imaging.
Researchers involved in the current project have secured
additional observation time on JWST to monitor similar high-redshift events.
These future campaigns will focus on detecting afterglows and host galaxies,
helping astronomers build a clearer picture of early stellar evolution.
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