https://arstechnica.com/science/2023/08/ryugu-samples-reveal-traces-of-rock-from-before-the-sun-existed/ Skip to main content * Biz & IT * Tech * Science * Policy * Cars * Gaming & Culture * Store * Forums Subscribe [ ] Close Navigate * Store * Subscribe * Videos * Features * Reviews * RSS Feeds * Mobile Site * About Ars * Staff Directory * Contact Us * Advertise with Ars * Reprints Filter by topic * Biz & IT * Tech * Science * Policy * Cars * Gaming & Culture * Store * Forums Settings Front page layout Grid List Site theme light dark Sign in Ancient history -- Ryugu samples reveal traces of rock from before the Sun existed Small bits of material in the asteroid contain isotopes made in specific stars. Elizabeth Rayne - Aug 2, 2023 8:30 pm UTC Grey image of a small asteroid's surface, showing many rocks and lots of dust. Enlarge / Ryugu's rubble pile includes some small fragments left over from our Solar System's formation. ISAS, JAXA reader comments 58 with When JAXA's Hayabusa-2 spacecraft delivered samples from asteroid Ryugu to Earth in late 2020, anticipation was high. What could the space rock possibly be waiting to tell us? Asteroids are time capsules of the Solar System, containing material from early in its history. As a 2021 study found, the Ryugu samples contained carbon, nitrogen, and oxygen, all necessary ingredients for life, and a 2022 study discovered evidence of water (and possibly a subsurface lake) that had long since dried up. Ryugu and its parent body were also revealed to carry some of the most ancient rocks in the Solar System. However, the pieces of this asteroid still had more to say. It turned out that two of the Ryugu samples each had a shard of something that visually stood out. Researchers discovered they were seeing fragments, or clasts, of rock with a chemical composition that differed from the rest of Ryugu. These clasts were higher in sulfur and iron, but lower in oxygen, magnesium, and silicon. That meant they could not have possibly formed with Ryugu, so they had to have been acquired through a later impact; but the asteroid still had more to say. Embedded in the clasts were tiny grains of rock made from stars that died before the Sun ever existed. "[The chemical makeup of] the primitive clasts compared to bulk Ryugu suggest that the clasts formed in a unique part of the protoplanetary disk enriched in presolar materials," the research team said in a study recently published in Science Advances. The stuff stars are made of The clasts in Ryugu samples C0002 and A0040 are now thought to have originated in the outer reaches of the Solar System. By using different types of electron microscopy along with energy-dispersive X-ray spectroscopy and nanoscale secondary ion mass spectrometry, the researchers determined what they were made of. The presolar silicate grains inside the clasts contained significant amounts of the isotope Carbon-13. Most of the grains were silicon carbide. This told the team that the presolar grains had formed around asymptotic giant branch (AGB) stars (which our Sun will become someday), although one of them showed signs of possible supernova origin. Advertisement Most stars are main sequence stars. After they have burned through the hydrogen in their core through nuclear fusion, they evolve into AGB stars, which are similar to red giants. Powerful winds blow the outer layers of these stars off until there is nothing left but a white dwarf. The majority of presolar grains found in the Ryugu clasts appeared to have come from AGB stars with a similar or lower metal content than the Sun, such as two presolar grains within sample C0002 that were high in the isotope oxygen-17. The ratio of oxygen-17 to oxygen-18 provides evidence of nucleosynthesis in stars, as high levels of oxygen-18 are only produced in supernovae. Some grains in Ryugu had an oxygen-17/18 ratio that matched that of AGB stars. Only one grain high in oxygen-18 showed a ratio consistent with a supernova. Traveling through deep time and space Traversing space was dangerous for those grains, because the materials in many of them cannot survive contact with water. This means the impact that brought them to Ryugu or its parent had to have happened sometime after the asteroid or parent lost its water. Because Ryugu's parent body probably formed at the edge of the Solar System and was pushed inward later by gravitational interactions, the researchers think it may have once contained more presolar grains that water ended up obliterating. There are some types of presolar grains that can survive water. Though presolar silicates won't make it, silicon carbide and graphite grains that predate the Sun will, and these were also found on Ryugu. Strangely enough, Ryugu had some chemical similarities to the comet Wild 2, which was sampled by NASA's Stardust mission, though it wasn't an exact match. This finding could still mean that at least some of the presolar grains found in Ryugu samples could have originally come from a comet. As we wait for samples from asteroid Bennu to touch down, it appears that Ryugu still has much to tell us about what the Solar System was like before we had a Sun. Science Advances, 2023. DOI: 10.1126/sciadv.adh1003 Elizabeth Rayne is a creature who writes. Her work has appeared on SYFY WIRE, Space.com, Live Science, Grunge, Den of Geek, and Forbidden Futures. When not writing, she is either shapeshifting, drawing, or cosplaying as a character nobody has ever heard of. Follow her on Twitter @quothravenrayne. reader comments 58 with Advertisement Channel Ars Technica - Previous story Next story - Related Stories Today on Ars * Store * Subscribe * About Us * RSS Feeds * View Mobile Site * Contact Us * Staff * Advertise with us * Reprints Newsletter Signup Join the Ars Orbital Transmission mailing list to get weekly updates delivered to your inbox. Sign me up - CNMN Collection WIRED Media Group (c) 2023 Conde Nast. All rights reserved. Use of and/or registration on any portion of this site constitutes acceptance of our User Agreement (updated 1/1/20) and Privacy Policy and Cookie Statement (updated 1/1 /20) and Ars Technica Addendum (effective 8/21/2018). Ars may earn compensation on sales from links on this site. Read our affiliate link policy. 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