Carbonaceous chondrite meteorites experienced fluid flow within the past million years

Simon Turner; Lucy McGee; Munir Humayun; John Creech; Brigitte Zanda

doi:10.1126/science.abc8116

Carbonaceous chondrite meteorites experienced fluid flow within the past million years

Simon Turner^*, Lucy McGee, Munir Humayun, John Creech, Brigitte Zanda

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

Carbonaceous chondritic meteorites are primordial Solar System materials and a source of water delivery to Earth. Fluid flow on the parent bodies of these meteorites is known to have occurred very early in Solar System history (first <4 million years). We analyze short-lived uranium isotopes in carbonaceous chondrites, finding excesses of 234-uranium over 238-uranium and 238-uranium over 230-thorium. These indicate that the fluid-mobile uranium ion U6+ moved within the past few 100,000 years. In some meteorites, this time scale is less than the cosmic-ray exposure age, which measures when they were ejected from their parent body into space. Fluid flow occurred after melting of ice, potentially by impact heating, solar heating, or atmospheric ablation. We favor the impact heating hypothesis, which implies that the parent bodies still contain ice.

Original language	English
Pages (from-to)	164-167
Number of pages	4
Journal	Science (New York, N.Y.)
Volume	371
Issue number	6525
DOIs	https://doi.org/10.1126/science.abc8116
Publication status	Published - 8 Jan 2021

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title = "Carbonaceous chondrite meteorites experienced fluid flow within the past million years",

abstract = "Carbonaceous chondritic meteorites are primordial Solar System materials and a source of water delivery to Earth. Fluid flow on the parent bodies of these meteorites is known to have occurred very early in Solar System history (first <4 million years). We analyze short-lived uranium isotopes in carbonaceous chondrites, finding excesses of 234-uranium over 238-uranium and 238-uranium over 230-thorium. These indicate that the fluid-mobile uranium ion U6+ moved within the past few 100,000 years. In some meteorites, this time scale is less than the cosmic-ray exposure age, which measures when they were ejected from their parent body into space. Fluid flow occurred after melting of ice, potentially by impact heating, solar heating, or atmospheric ablation. We favor the impact heating hypothesis, which implies that the parent bodies still contain ice.",

author = "Simon Turner and Lucy McGee and Munir Humayun and John Creech and Brigitte Zanda",

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T1 - Carbonaceous chondrite meteorites experienced fluid flow within the past million years

AU - Turner, Simon

AU - McGee, Lucy

AU - Humayun, Munir

AU - Creech, John

AU - Zanda, Brigitte

PY - 2021/1/8

Y1 - 2021/1/8

N2 - Carbonaceous chondritic meteorites are primordial Solar System materials and a source of water delivery to Earth. Fluid flow on the parent bodies of these meteorites is known to have occurred very early in Solar System history (first <4 million years). We analyze short-lived uranium isotopes in carbonaceous chondrites, finding excesses of 234-uranium over 238-uranium and 238-uranium over 230-thorium. These indicate that the fluid-mobile uranium ion U6+ moved within the past few 100,000 years. In some meteorites, this time scale is less than the cosmic-ray exposure age, which measures when they were ejected from their parent body into space. Fluid flow occurred after melting of ice, potentially by impact heating, solar heating, or atmospheric ablation. We favor the impact heating hypothesis, which implies that the parent bodies still contain ice.

AB - Carbonaceous chondritic meteorites are primordial Solar System materials and a source of water delivery to Earth. Fluid flow on the parent bodies of these meteorites is known to have occurred very early in Solar System history (first <4 million years). We analyze short-lived uranium isotopes in carbonaceous chondrites, finding excesses of 234-uranium over 238-uranium and 238-uranium over 230-thorium. These indicate that the fluid-mobile uranium ion U6+ moved within the past few 100,000 years. In some meteorites, this time scale is less than the cosmic-ray exposure age, which measures when they were ejected from their parent body into space. Fluid flow occurred after melting of ice, potentially by impact heating, solar heating, or atmospheric ablation. We favor the impact heating hypothesis, which implies that the parent bodies still contain ice.

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DO - 10.1126/science.abc8116

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EP - 167

JO - Science (New York, N.Y.)

JF - Science (New York, N.Y.)

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ER -

Carbonaceous chondrite meteorites experienced fluid flow within the past million years

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