Evidence for the Late Formation of Hydrous Asteroids from Young Meteoritic Carbonates

Overview

Journal Nat Commun

Specialty Biology

Date 2012 Jan 19

PMID 22252551

Citations 18

Authors

Wataru Fujiya

Naoji Sugiura

Hideyuki Hotta

Koji Ichimura

Yuji Sano

Affiliations

Soon will be listed here.

Abstract

The accretion of small bodies in the Solar System is a fundamental process that was followed by planet formation. Chronological information of meteorites can constrain when asteroids formed. Secondary carbonates show extremely old (53)Mn-(53)Cr radiometric ages, indicating that some hydrous asteroids accreted rapidly. However, previous studies have failed to define accurate Mn/Cr ratios; hence, these old ages could be artefacts. Here we develop a new method for accurate Mn/Cr determination, and report a reliable age of 4,563.4+0.4/-0.5 million years ago for carbonates in carbonaceous chondrites. We find that these carbonates have identical ages, which are younger than those previously estimated. This result suggests the late onset of aqueous activities in the Solar System. The young carbonate age cannot be explained if the parent asteroid accreted within 3 million years after the birth of the Solar System. Thus, we conclude that hydrous asteroids accreted later than differentiated and metamorphosed asteroids.

Citing Articles

Low-Temperature Aqueous Alteration of Chondrites.

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The Ni isotopic composition of Ryugu reveals a common accretion region for carbonaceous chondrites.

Spitzer F, Kleine T, Burkhardt C, Hopp T, Yokoyama T, Abe Y Sci Adv. 2024; 10(39):eadp2426.

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Breunnerite grain and magnesium isotope chemistry reveal cation partitioning during aqueous alteration of asteroid Ryugu.

Yoshimura T, Araoka D, Naraoka H, Sakai S, Ogawa N, Yurimoto H Nat Commun. 2024; 15(1):6809.

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