The interstellar stuff that became incorporated into the planets and life on Earth has younger cosmic roots than theories predict, according to Philipp Heck at the University of Chicago, and his international team.
Heck and his colleagues examined 22 interstellar grains from the Murchison meteorite. Dying Sun-like stars flung the Murchison grains into space more than 4.5 billion years ago, before the birth of the solar system. Scientists know the grains formed outside the solar system because of their exotic composition.
"The concentration of neon, produced during cosmic-ray irradiation, allows us to determine the time a grain has spent in interstellar space," Heck said. His team determined that 17 of the grains spent somewhere between 3 million and 200 million years in interstellar space, far less than the theoretical estimates of approximately 500 million years. Only three grains met interstellar duration expectations (two grains yielded no reliable age).
"The knowledge of this lifetime is essential for an improved understanding of interstellar processes, and to better contain the timing of formation processes of the solar system," Heck said. A period of intense star formation that preceded the Sun's birth may have produced large quantities of dust, thus accounting for the timing discrepancy, according to the research team.
Heck and his colleagues examined 22 interstellar grains from the Murchison meteorite. Dying Sun-like stars flung the Murchison grains into space more than 4.5 billion years ago, before the birth of the solar system. Scientists know the grains formed outside the solar system because of their exotic composition.
"The concentration of neon, produced during cosmic-ray irradiation, allows us to determine the time a grain has spent in interstellar space," Heck said. His team determined that 17 of the grains spent somewhere between 3 million and 200 million years in interstellar space, far less than the theoretical estimates of approximately 500 million years. Only three grains met interstellar duration expectations (two grains yielded no reliable age).
"The knowledge of this lifetime is essential for an improved understanding of interstellar processes, and to better contain the timing of formation processes of the solar system," Heck said. A period of intense star formation that preceded the Sun's birth may have produced large quantities of dust, thus accounting for the timing discrepancy, according to the research team.
No comments:
Post a Comment