A newly discovered ancient star containing a record-low amount of iron carries evidence of a class of even older stars, long hypothesised but assumed to have vanished.
In a paper published in the journal Monthly Notices of the Royal Astronomical Society: Letters, researchers led by Dr. Thomas Nordlander of the ARC Centre of Excellence for All Sky Astrophysics in 3 Dimensions (ASTRO 3-D) confirm the existence of an ultra-metal-poor red giant star, located in the halo of the Milky Way, on the other side of the Galaxy about 35,000 light-years from Earth.
Dr. Nordlander, from the Australian National University (ANU) node of ASTRO 3-D, together with colleagues from Australia, the US and Europe, located the star using the university’s dedicated SkyMapper Telescope at the Siding Springs Observatory in NSW.
Spectroscopic analysis indicated that the star had an iron content of just one part per 50 billion.
“That’s like one drop of water in an Olympic swimming pool,” explains Dr. Nordlander.
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“This incredibly anaemic star, which likely formed just a few hundred million years after the Big Bang, has iron levels 1.5 million times lower than that of the Sun.”
Its diminutive iron content is enough to place the star—formally dubbed SMSS J160540.18–144323.1—into the record books, but it is what that low level implies about its origin that has the astronomers really excited.
The very first stars in the Universe are thought to have consisted of only hydrogen and helium, along with traces of lithium. These elements were created in the immediate aftermath of the Big Bang, while all heavier elements have emerged from the heat and pressure of cataclysmic supernovae—titanic explosions of stars. Stars like the Sun that are rich in heavy element therefore contain material from many generations of stars exploding as supernovae.
As none of the first stars have yet been found, their properties remain hypothetical. They were long expected to have been incredibly massive, perhaps hundreds of times more massive than the Sun, and to have exploded in incredibly energetic supernovae known as hypernovae.
The confirmation of the anaemic SMSS J160540.18–144323.1, although itself not one of the first stars, adds a powerful bit of evidence.
Dr. Nordlander and colleagues suggest that the star was formed after one of the first stars exploded. That exploding star is found to have been rather unimpressive, just ten times more massive than the Sun, and to have exploded only feebly (by astronomical scales) so that most of the heavy elements created in the supernova fell back into the remnant neutron star left behind.
Only a small amount of newly forged iron escaped the remnant’s gravitational pull and went on, in concert with far larger amounts of lighter elements, to form a new star—one of the very first second generation stars, that has now been discovered.
Co-researcher Professor Martin Asplund, a chief investigator of ASTRO 3-D at ANU, said it was unlikely that any true first stars have survived to the present day.
“The good news is that we can study the first stars through their children—the stars that came after them like the one we’ve discovered,” he says.
The study was conducted in collaboration with researchers from Monash University and the University of New South Wales in Australia, the Massachusetts Institute of Technology and Joint Institute for Nuclear Astrophysics, both in the U.S., the Max Planck Institute for Astronomy in Germany, Uppsala University in Sweden, and the University of Padova in Italy.
Provided by: The ARC Centre of Excellence for All Sky Astrophysics in 3 Dimensions
More information: T Nordlander et al. The lowest detected stellar Fe abundance: the halo star SMSS J160540.18−144323.1. Monthly Notices of the Royal Astronomical Society: Letters (2019). DOI: 10.1093/mnrasl/slz109
Image Credit: CC0 Public Domain