Astronomers using the VLT found a distant gas clouds with leftovers of the first stars
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This artist’s impression shows
a distant gas cloud that contains different chemical elements, illustrated here
with schematic representations of various atoms.
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Using ESO’s Very Large
Telescope, astronomers have detected three distant gas clouds whose chemical
composition matches what we expect from the explosions of the first stars that
appeared in the Universe. These early stars can be studied indirectly by
analysing the chemical elements they dispersed into the surrounding environment
after they died in supernova explosions. The three distant gas clouds detected
in this study are rich in carbon, oxygen, and magnesium, but poor in iron. This
is exactly the signature expected from the explosions of the first stars. Credit: ESO/L. Calçada, M. Kornmesser |
Using
ESO’s Very Large Telescope (VLT), researchers have found for the first time the
fingerprints left by the explosion of the first stars in the Universe. They
detected three distant gas clouds whose chemical composition matches what we
expect from the first stellar explosions. These findings bring us one step
closer to understanding the nature of the first stars that formed after the Big
Bang.
“For the first time ever,
we were able to identify the chemical traces of the explosions of the first
stars in very distant gas clouds,” says Andrea Saccardi, a PhD student at
the Observatoire de Paris - PSL, who led this study during his master’s thesis
at the University of Florence.
Researchers think that the first stars (or Population III stars) that formed in the Universe were very different from the ones we see today. When they appeared 13.5 billion years ago, they contained just hydrogen and helium, the simplest chemical elements in nature [1]. These stars, thought to be tens or hundreds of times more massive than our Sun, quickly died in powerful explosions known as supernovae, enriching the surrounding gas with heavier elements for the first time. Later generations of stars were born out of that enriched gas, and in turn ejected heavier elements as they too died. But the very first stars are now long gone, so how can researchers learn more about them? “Primordial stars can be studied indirectly by detecting the chemical elements they dispersed in their environment after their death,” says Stefania Salvadori, Associate Professor at the University of Florence and co-author of the study published today in the Astrophysical Journal.
Using data taken with ESO’s
VLT in Chile, the team found three very distant gas clouds, seen when the
Universe was just 10–15% of its current age, and with a chemical fingerprint
matching what we expect from the explosions of the first stars. Depending on
the mass of these early stars and the energy of their explosions, these first
supernovae released different chemical elements such as carbon, oxygen and
magnesium, which are present in the outer layers of stars. But some of these
explosions were not energetic enough to expel heavier elements like iron, which
is found only in the cores of stars. To search for the telltale sign of these
very first stars that exploded as low energy supernovae, the team therefore
looked for distant gas clouds poor in iron but rich in the other elements. And
they found just that: three faraway clouds in the early Universe with very
little iron but plenty of carbon and other elements — the fingerprint of the
explosions of the very first stars.
This peculiar chemical
composition has also been observed in many old stars in our own galaxy, which
researchers consider to be second-generation stars that formed directly from
the ‘ashes’ of the first ones. This new study has found such ashes in the early
Universe, thus adding a missing piece to this puzzle. “Our discovery opens
new avenues to indirectly study the nature of the first stars, fully
complementing studies of stars in our galaxy,” explains Salvadori.
To detect and study these
distant gas clouds, the team used light beacons known as quasars — very bright
sources powered by supermassive black holes at the centres of faraway galaxies.
As the light from a quasar travels through the Universe, it passes through gas
clouds where different chemical elements leave an imprint on the light.
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This diagram illustrates how
astronomers can analyse the chemical composition of distant clouds of gas using
the light of a background object like a quasar as a beacon.
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When the light of the quasar
passes through the gas cloud, the chemical elements in it absorb different
colours or wavelengths, leaving dark lines in the spectrum of the quasar. Each
element leaves a different set of lines, so by studying the spectrum
astronomers can work out the chemical composition of the intervening gas cloud. Credit: ESO/L. Calçada |
To find these chemical imprints, the team analysed data on several quasars observed with the X-shooter instrument on ESO’s VLT. X-shooter splits light into an extremely wide range of wavelengths, or colours, which makes it a unique instrument with which to identify many different chemical elements in these distant clouds.
This study opens new windows
for next generation telescopes and instruments, like ESO’s upcoming Extremely
Large Telescope (ELT) and its
high-resolution ArmazoNes high Dispersion Echelle Spectrograph (ANDES). “With ANDES at the ELT we will be able to study
many of these rare gas clouds in greater detail, and we will be able to finally
uncover the mysterious nature of the first stars,” concludes Valentina
D’Odorico, a researcher at the National Institute of Astrophysics in Italy and
co-author of the study.
Notes
[1] Minutes after the Big Bang
the only elements present in the Universe were the three lightest ones:
hydrogen, helium and very small traces of lithium. Heavier
elements were formed much later on in stars.
More
information: Evidence of first stars-enriched gas in high-redshift
absorbers, The Astrophysical Journal (2023). DOI: 10.3847/1538-4357/acc39f
Source: ESO
