(Santa Barbara, CA) With the help of enormous computer simulations, astronomers have now shown that the first generation of stars which have never been observed by scientists should be distributed evenly throughout our galaxy, deepening the long-standing mystery about these missing stellar ancestors. The results are published in this week's issue of the Astrophysical Journal.
The problem is that despite years of looking, no one has ever found any of these stars. "Many astronomers thought this was because the stars without heavy elements were hidden from us," said Evan Scannapieco, first author and a postdoctoral fellow at the Kavli Institute for Theoretical Physics at the University of California, Santa Barbara. "Because our galaxy formed from the inside out, the idea was that these very old stars would all be near the center. But the center of Milky Way is extremely crowded with dust and newer stars, making it very hard to detect individual old stars in this environment."
This earliest generation of stars should look very different from later-forming stars like the Sun; yet so far, no one has detected a survivor from this primordial population. One of the long-standing explanations for this discrepancy was that these stars might all be contained in regions near the center of the Milky Way, where they are very hard to observe. The results of the new study make that explanation unlikely.
Oxygen, carbon, and most of the elements we encounter every day on Earth were made in stars, rather than during the Big Bang. "But these heavy elements are made in the centers of stars and remain buried under the gas at the surface until the stars die and explode, so what you see when you look at a star are the elements that were present when it was born," said Brad K. Gibson, co-author and chair of the Department of Theoretical Astrophysics at the University of Central Lancashire in Britain. "This means that the stars still living from this first generation should continue to show no heavy elements."
Carrying out a detailed simulation of the formation of the Milky Way, the research group constructed not only the history of where stars formed over time, but the chemical composition of the gas out of which these stars formed. "We found that while the very oldest stars all end up near the center of the Milky Way, it takes a long time for heavy elements to enrich the gas that is further out," said co-author Daisuke Kawata, a scientist with the Carnegie Observatories in Pasadena, California. "This means that while the oldest stars all end up near the center of the galaxy, plenty of stars that contain only primordial elements are formed at later times throughout the galaxy. These primordial stars should be everywhere."
Because the stars forming in the Milky Way suburbs are easily detectable with present day telescopes, there must be some other reason that the remnants of this primordial generation didn't survive. "It could be that they were all high-mass stars, which would not have lived long enough to still be around, or there could be another twist to the story that we haven't yet figured out," said co-investigator Chris Brook, a scientist with the University of Washington. "Whatever the answer, it's clear that studies of the outskirts of our galaxy will have lots more to tell us about this remarkable, missing generation."
Other scientists involved in the research were Andrea Ferrara of the International School for Advanced Studies in Trieste, Italy and Rafaella Schneider of the Arctri Observatory in Florence, Italy.
Note To Editors: Evan Scannapieco is available at 415-425-7073, or by e-mail at email@example.com
Daisuke Kawata is available at 626-304-0232 or by e-mail at firstname.lastname@example.org, or through his press contact Arnold Phifer at Carnegie Observatories at 626-304-0270, or by e-mail at email@example.com
Brad Gibson is available at +44 (0) 1772 893585 or by e-mail at firstname.lastname@example.org
Brad Gibson's press contact, Samantha Coventry, is available at the University of Central Lancashire at +44 (0) 1772 894423 or by e-mail at email@example.com
Chris Brook is available at 206-616-5001, or by e-mail at firstname.lastname@example.org
Chris Brook's press contact at the University of Washington is Vince Stricherz, available at 206-543-2580, or by e-mail at email@example.com
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