Astronomers find possible first evidence for supermassive stars at the origin of globular clusters
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Scientists have found strong evidence that supermassive stars existed within globular clusters when they formed 13 billion years ago. Here, an image of the globular cluster M13 in Hercules, 22,000 light years from Earth, consisting of a million stars squeezed into a space 150 light years across. Credit: HST STScI NASA ESA.
A team from the universities of Geneva, Paris and Barcelona has found strong evidence that supermassive stars can explain the anomalies observed in large clusters of stars.
Globular clusters are
the most massive and oldest star clusters in the Universe. They can contain up
to 1 million of them. The chemical composition of these stars, born at the same
time, shows anomalies that are not found in any other population of stars.
Explaining this specificity is one of the great challenges of astronomy. After having
imagined that supermassive stars could be at the origin, a team from the
Universities of Geneva and Barcelona, and the Institut d’Astrophysique de Paris
(CNRS and Sorbonne University) believes it has discovered the first chemical
trace attesting to their presence in globular proto-clusters, born about 440
million years after the Big Bang. These results, obtained thanks to
observations by the James-Webb space telescope, are to be found in Astronomyand Astrophysics.
Globular clusters are very dense groupings of
stars distributed in a sphere, with a radius varying from a dozen to a hundred
light years. They can contain up to 1 million stars and are found in all types
of galaxies. Ours is home to about 180 of them. One of their great mysteries is
the composition of their stars: why is it so varied? For instance, the
proportion of oxygen, nitrogen, sodium and aluminium varies from one star to
another. However, they were all born at the same time, within the same cloud of
gas. Astrophysicists speak of ‘‘abundance anomalies’’.
Monsters with very short lives
A team from the universities of Geneva (UNIGE)
and Barcelona, and the Institut d’Astrophysique de Paris (CNRS and Sorbonne
University) has made a new advance in the explanation of this phenomenon. In 2018,
it had developed a theoretical model according to which supermassive stars
would have «polluted» the original gas cloud during the formation of these
clusters, enriching their stars with chemical elements in a heterogeneous
manner. ‘‘Today, thanks to the data collected by the James-Webb Space
Telescope, we believe we have found a first clue of the presence of these
extraordinary stars,’’ explains Corinne Charbonnel, a full professor in the
Department of Astronomy at the UNIGE Faculty of Science, and first author of
the study.
These celestial monsters are 5 000 to 10 000
times more massive and five times hotter at their centre (75 million °C) than
the Sun. But proving their existence is complex. ‘‘Globular clusters are
between 10 and 13 billion years old, whereas the maximum lifespan of superstars
is two million years. They therefore disappeared very early from the clusters
that are currently observable. Only indirect traces remain,’’ explains Mark
Gieles, ICREA professor at the University of Barcelona and co-author of the
study.
Revealed by light
Thanks to the very powerful infrared vision of
the James-Webb telescope, the co-authors were able to support their hypothesis.
The satellite captured the light emitted by one of the most distant and
youngest galaxies known to date in our Universe. Located at about 13.3 billion
light-years, GN-z11 is only
a few tens of millions of years old. In astronomy, the analysis of the light
spectrum of cosmic objects is a key element in determining their
characteristics. Here, the light emitted by this galaxy has provided two
valuable pieces of information.
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Hubble Space
Telescope astronomers, studying the northern hemisphere field from the Great
Observatories Origins Deep Survey (GOODS), have measured the distance to the
farthest galaxy ever seen. The survey field contains tens of thousands of
galaxies stretching far back into time. Galaxy GN-z11, shown in the inset, is
seen as it was 13.4 billion years in the past, just 400 million years after the
big bang, when the universe was only three percent of its current age. The
galaxy is ablaze with bright, young, blue stars, but looks red in this image
because its light has been stretched to longer spectral wavelengths by the
expansion of the universe. Credit: ASA, ESA, P. Oesch (Yale University), G.
Brammer (STScI), P. van Dokkum (Yale University), and G. Illingworth
(University of California, Santa Cruz).
‘‘It has been established that it contains very high proportions of nitrogen and a very high density of stars,’’ says Daniel Schaerer, associate professor in the Department of Astronomy at the UNIGE Faculty of Science, and co-author of the study. This suggests that several globular clusters are forming in this galaxy and that they still harbour an active supermassive star. ‘‘The strong presence of nitrogen can only be explained by the combustion of hydrogen at extremely high temperatures, which only the core of supermassive stars can reach, as shown by the models of Laura Ramirez-Galeano, a Master’s student in our team,’’ explains Corinne Charbonnel.
These new results strengthen the international
team’s model. The only one currently capable of explaining the abundance
anomalies in globular clusters. The next step for the scientists will be to
test the validity of this model on other globular clusters forming in distant
galaxies, using the James-Webb data.
Source: University of Geneva
