SPring-8, the large synchrotron radiation facility

Researcher undertaken at Tohoku University has discovered fossil asteroidal ice within a meteorite. Performing a high-resolution CT imaging of a primitive, 4.6 billion years old meteorite, researchers discovered µm-sized ultra-porous regions inside the meteorite. The porous texture is highly likely to have formed when the previously ice-filled pore spaces disappeared, suggesting that the ultra-porous regions represent primordial ice fossils.

Based on the discovery, the research team proposed a new practical model indicating that the meteorite parent body (a planetesimal) formed by icy dust agglomeration through radial migration from the outer to inner regions of the early Solar System, across the H₂o snow line. Their findings provide further insights into the formation of asteroids in the early Solar System.

Asteroids formed in the outer region of the H₂o snow line are thought to have contained some ice upon formation. It is known that there exists a large number of meteorites seeming to have experienced aqueous alteration caused by ice melting in asteroids. However, researchers have yet to discover how the primordial ice responsible for the aqueous alteration was distributed to the meteorite parent bodies.

The researchers examined meteorite Acfer 094 and discovered fossil asteroidal ice within it. Based on their microscopic observations, they hypothesize that the ice was originally formed by the sintering of fluffy icy dust around the H₂o snow line and subsequently incorporated into the meteorite parent body. The sintering process converted the fluffy icy dust into solid ice-silicate aggregates which were resistant to compaction in the meteorite parent body.

The incorporation of the aggregates into the meteorite parent body occurred around the H₂o snow line during the radial migration of the parent body from the outer to inner regions of the early Solar System. After the incorporation, ice in the aggregates disappeared when an increase in temperature caused evaporation and/or melting. This resulted in the formation of ultra-porous regions inside the meteorites.

These findings are important in terms of providing new insight to understanding of asteroid formation in the early Solar System. The details are described in a paper published by Science Advances online.

Publication Details:
Title: Discovery of fossil asteroidal ice in primitive meteorite Acfer 094
Authors: Megumi Matsumoto, Akira Tsuchiyama, Aiko Nakato, Junya Matsuno, Akira Miyake, Akimasa Kataoka, Motoo Ito, Naotaka Tomioka, Yu Kodama, Kentaro Uesugi, Akihisa Takeuchi, Tsukasa Nakano, Epifanio Vaccaro.
Journal: Science Advances
DOI: 10.1126/sciadv.aax5078
Embargo date: 20 November, 2:00pm U.S. Eastern Time