Origin of metal from CB chondrites in an impact plume: A combined study of Fe and Ni isotope composition and trace element abundances

Research output: Contribution to journalArticleResearchpeer review

Authors

Research Organisations

External Research Organisations

  • Senckenberg Research
View graph of relations

Details

Original languageEnglish
Pages (from-to)123-137
Number of pages15
JournalGeochimica et cosmochimica acta
Volume246
Early online date24 Nov 2018
Publication statusPublished - 1 Feb 2019

Abstract

The formation processes of the unusually metal-rich CB chondrites are a matter of debate. It is widely accepted that metal grains have formed by condensation. However, it is still debated whether they condensed directly from the solar nebula or from an impact-induced vapor plume. In this study, we present high precision Fe and Ni isotope and trace element composition of zoned and unzoned metal grains from the CBb chondrites Hammadah al Hamra 237, QUE 94411, and MAC 02675, and the CH/CBb breccia Isheyevo and unzoned metal from the CBa chondrites Bencubbin, Gujba, and NWA 4025. Data were obtained using femtosecond laser ablation (multicollector) inductively coupled plasma mass spectrometry (fs-LA-(MC)-ICP-MS). Zoned metal grains from CBb meteorites generally display parallel profiles of Ni and Fe isotope compositions with very low δ56Fe and δ60Ni, and elevated concentrations of refractory siderophile elements in their cores. These findings are consistent with dominantly kinetic isotope- and trace element fractionation during condensation from a confined and fast cooling gas reservoir. Tungsten and Mo are frequently depleted relative to other refractory elements, particularly in zoned metal grains, which is suggestive for elevated oxygen fugacities in the gas reservoir. Such conditions are indicative of the formation of these metal grains during an impact event. Compared to zoned metal, unzoned metal grains are isotopically more homogeneous and more similar to the heavier rims of the zoned metal grains. This indicates that they formed under different conditions than the zoned metals, i.e., in a more slowly cooling environment. However, several unzoned grains still display significantly variable and correlated δ56Fe and δ60Ni, suggesting that their formation was related to that of the zoned metal grains. The kinetic fractionation-dominated isotopic signatures of the zoned metal grains strongly point to their formation during fast cooling, as may be expected for the exterior envelope of an impact plume. In contrast, the more homogenous isotopic signatures of the unzoned metal grains are more consistent with dominantly equilibrium-like isotope fractionation during condensation, as may be expected for the interior of an impact plume. In this scenario, the isotopically heavier rims of the zoned grains are best explained by a depletion of the outer plume gas reservoir in refractory elements and light isotopes. Accordingly, these findings indicate that zoned and unzoned metal grains likely formed during the same event. The compositional differences among individual unzoned metal grains, but also within some of the zoned grains, indicate turbulent gas mixing, also including movement of metals during their formation, between inner and outer regions of the impact plume.

Keywords

    CB chondrites, Condensation, Fe and Ni isotopes, Impact plume, Zoned metal

ASJC Scopus subject areas

Cite this

Origin of metal from CB chondrites in an impact plume: A combined study of Fe and Ni isotope composition and trace element abundances. / Weyrauch, M.; Zipfel, J.; Weyer, S.
In: Geochimica et cosmochimica acta, Vol. 246, 01.02.2019, p. 123-137.

Research output: Contribution to journalArticleResearchpeer review

Download
@article{8ae4f35fd1814f8f946d3c08e6bf9841,
title = "Origin of metal from CB chondrites in an impact plume: A combined study of Fe and Ni isotope composition and trace element abundances",
abstract = "The formation processes of the unusually metal-rich CB chondrites are a matter of debate. It is widely accepted that metal grains have formed by condensation. However, it is still debated whether they condensed directly from the solar nebula or from an impact-induced vapor plume. In this study, we present high precision Fe and Ni isotope and trace element composition of zoned and unzoned metal grains from the CBb chondrites Hammadah al Hamra 237, QUE 94411, and MAC 02675, and the CH/CBb breccia Isheyevo and unzoned metal from the CBa chondrites Bencubbin, Gujba, and NWA 4025. Data were obtained using femtosecond laser ablation (multicollector) inductively coupled plasma mass spectrometry (fs-LA-(MC)-ICP-MS). Zoned metal grains from CBb meteorites generally display parallel profiles of Ni and Fe isotope compositions with very low δ56Fe and δ60Ni, and elevated concentrations of refractory siderophile elements in their cores. These findings are consistent with dominantly kinetic isotope- and trace element fractionation during condensation from a confined and fast cooling gas reservoir. Tungsten and Mo are frequently depleted relative to other refractory elements, particularly in zoned metal grains, which is suggestive for elevated oxygen fugacities in the gas reservoir. Such conditions are indicative of the formation of these metal grains during an impact event. Compared to zoned metal, unzoned metal grains are isotopically more homogeneous and more similar to the heavier rims of the zoned metal grains. This indicates that they formed under different conditions than the zoned metals, i.e., in a more slowly cooling environment. However, several unzoned grains still display significantly variable and correlated δ56Fe and δ60Ni, suggesting that their formation was related to that of the zoned metal grains. The kinetic fractionation-dominated isotopic signatures of the zoned metal grains strongly point to their formation during fast cooling, as may be expected for the exterior envelope of an impact plume. In contrast, the more homogenous isotopic signatures of the unzoned metal grains are more consistent with dominantly equilibrium-like isotope fractionation during condensation, as may be expected for the interior of an impact plume. In this scenario, the isotopically heavier rims of the zoned grains are best explained by a depletion of the outer plume gas reservoir in refractory elements and light isotopes. Accordingly, these findings indicate that zoned and unzoned metal grains likely formed during the same event. The compositional differences among individual unzoned metal grains, but also within some of the zoned grains, indicate turbulent gas mixing, also including movement of metals during their formation, between inner and outer regions of the impact plume.",
keywords = "CB chondrites, Condensation, Fe and Ni isotopes, Impact plume, Zoned metal",
author = "M. Weyrauch and J. Zipfel and S. Weyer",
note = "Funding information: We want to thank Julian Feige and Tina Emmel for sample preparation. Moreover, we thank Heidi H{\"o}fer and Markus Sch{\"o}lmerich for technical support at the electron microprobe in Frankfurt, and Renat Almeev and Chao Zhang for their support with EMPA in Hannover. We also want to thank Martin Oeser, Stephan Schuth and Ingo Horn for their technical support with LA-ICP-MS analyses. Moreover, we appreciate the fruitful discussions with Herbert Palme. The manuscript greatly benefitted from reviews by C. M. Alexander, M. I. Petaev, and an anonymous reviewer. Antarctic meteorite samples QUE 94411 (USNM 6840 8b) and MAC 02675,9 were kindly provided from the Meteorite Working Group. US Antarctic meteorite samples are recovered by the Antarctic Search for Meteorites (ANSMET) program which has been funded by NSF and NASA, and characterized and curated by the Department of Mineral Sciences of the Smithsonian Institution and Astromaterials Curation Office at NASA Johnson Space Center. Samples of Bencubbin, Gujba, HaH237, and Isheyevo were provided by the Senckenberg Forschungsinstitut und Naturmuseum Frankfurt. This work was supported by the German Research Foundation (DFG) within the Priority Program “The first 10 Million Years – a Planetary Materials Approach” ( SPP 1385 ) ( WE 2850/13-1 and ZI 1196/3-1 ).",
year = "2019",
month = feb,
day = "1",
doi = "10.1016/j.gca.2018.11.022",
language = "English",
volume = "246",
pages = "123--137",
journal = "Geochimica et cosmochimica acta",
issn = "0016-7037",
publisher = "Elsevier Ltd.",

}

Download

TY - JOUR

T1 - Origin of metal from CB chondrites in an impact plume

T2 - A combined study of Fe and Ni isotope composition and trace element abundances

AU - Weyrauch, M.

AU - Zipfel, J.

AU - Weyer, S.

N1 - Funding information: We want to thank Julian Feige and Tina Emmel for sample preparation. Moreover, we thank Heidi Höfer and Markus Schölmerich for technical support at the electron microprobe in Frankfurt, and Renat Almeev and Chao Zhang for their support with EMPA in Hannover. We also want to thank Martin Oeser, Stephan Schuth and Ingo Horn for their technical support with LA-ICP-MS analyses. Moreover, we appreciate the fruitful discussions with Herbert Palme. The manuscript greatly benefitted from reviews by C. M. Alexander, M. I. Petaev, and an anonymous reviewer. Antarctic meteorite samples QUE 94411 (USNM 6840 8b) and MAC 02675,9 were kindly provided from the Meteorite Working Group. US Antarctic meteorite samples are recovered by the Antarctic Search for Meteorites (ANSMET) program which has been funded by NSF and NASA, and characterized and curated by the Department of Mineral Sciences of the Smithsonian Institution and Astromaterials Curation Office at NASA Johnson Space Center. Samples of Bencubbin, Gujba, HaH237, and Isheyevo were provided by the Senckenberg Forschungsinstitut und Naturmuseum Frankfurt. This work was supported by the German Research Foundation (DFG) within the Priority Program “The first 10 Million Years – a Planetary Materials Approach” ( SPP 1385 ) ( WE 2850/13-1 and ZI 1196/3-1 ).

PY - 2019/2/1

Y1 - 2019/2/1

N2 - The formation processes of the unusually metal-rich CB chondrites are a matter of debate. It is widely accepted that metal grains have formed by condensation. However, it is still debated whether they condensed directly from the solar nebula or from an impact-induced vapor plume. In this study, we present high precision Fe and Ni isotope and trace element composition of zoned and unzoned metal grains from the CBb chondrites Hammadah al Hamra 237, QUE 94411, and MAC 02675, and the CH/CBb breccia Isheyevo and unzoned metal from the CBa chondrites Bencubbin, Gujba, and NWA 4025. Data were obtained using femtosecond laser ablation (multicollector) inductively coupled plasma mass spectrometry (fs-LA-(MC)-ICP-MS). Zoned metal grains from CBb meteorites generally display parallel profiles of Ni and Fe isotope compositions with very low δ56Fe and δ60Ni, and elevated concentrations of refractory siderophile elements in their cores. These findings are consistent with dominantly kinetic isotope- and trace element fractionation during condensation from a confined and fast cooling gas reservoir. Tungsten and Mo are frequently depleted relative to other refractory elements, particularly in zoned metal grains, which is suggestive for elevated oxygen fugacities in the gas reservoir. Such conditions are indicative of the formation of these metal grains during an impact event. Compared to zoned metal, unzoned metal grains are isotopically more homogeneous and more similar to the heavier rims of the zoned metal grains. This indicates that they formed under different conditions than the zoned metals, i.e., in a more slowly cooling environment. However, several unzoned grains still display significantly variable and correlated δ56Fe and δ60Ni, suggesting that their formation was related to that of the zoned metal grains. The kinetic fractionation-dominated isotopic signatures of the zoned metal grains strongly point to their formation during fast cooling, as may be expected for the exterior envelope of an impact plume. In contrast, the more homogenous isotopic signatures of the unzoned metal grains are more consistent with dominantly equilibrium-like isotope fractionation during condensation, as may be expected for the interior of an impact plume. In this scenario, the isotopically heavier rims of the zoned grains are best explained by a depletion of the outer plume gas reservoir in refractory elements and light isotopes. Accordingly, these findings indicate that zoned and unzoned metal grains likely formed during the same event. The compositional differences among individual unzoned metal grains, but also within some of the zoned grains, indicate turbulent gas mixing, also including movement of metals during their formation, between inner and outer regions of the impact plume.

AB - The formation processes of the unusually metal-rich CB chondrites are a matter of debate. It is widely accepted that metal grains have formed by condensation. However, it is still debated whether they condensed directly from the solar nebula or from an impact-induced vapor plume. In this study, we present high precision Fe and Ni isotope and trace element composition of zoned and unzoned metal grains from the CBb chondrites Hammadah al Hamra 237, QUE 94411, and MAC 02675, and the CH/CBb breccia Isheyevo and unzoned metal from the CBa chondrites Bencubbin, Gujba, and NWA 4025. Data were obtained using femtosecond laser ablation (multicollector) inductively coupled plasma mass spectrometry (fs-LA-(MC)-ICP-MS). Zoned metal grains from CBb meteorites generally display parallel profiles of Ni and Fe isotope compositions with very low δ56Fe and δ60Ni, and elevated concentrations of refractory siderophile elements in their cores. These findings are consistent with dominantly kinetic isotope- and trace element fractionation during condensation from a confined and fast cooling gas reservoir. Tungsten and Mo are frequently depleted relative to other refractory elements, particularly in zoned metal grains, which is suggestive for elevated oxygen fugacities in the gas reservoir. Such conditions are indicative of the formation of these metal grains during an impact event. Compared to zoned metal, unzoned metal grains are isotopically more homogeneous and more similar to the heavier rims of the zoned metal grains. This indicates that they formed under different conditions than the zoned metals, i.e., in a more slowly cooling environment. However, several unzoned grains still display significantly variable and correlated δ56Fe and δ60Ni, suggesting that their formation was related to that of the zoned metal grains. The kinetic fractionation-dominated isotopic signatures of the zoned metal grains strongly point to their formation during fast cooling, as may be expected for the exterior envelope of an impact plume. In contrast, the more homogenous isotopic signatures of the unzoned metal grains are more consistent with dominantly equilibrium-like isotope fractionation during condensation, as may be expected for the interior of an impact plume. In this scenario, the isotopically heavier rims of the zoned grains are best explained by a depletion of the outer plume gas reservoir in refractory elements and light isotopes. Accordingly, these findings indicate that zoned and unzoned metal grains likely formed during the same event. The compositional differences among individual unzoned metal grains, but also within some of the zoned grains, indicate turbulent gas mixing, also including movement of metals during their formation, between inner and outer regions of the impact plume.

KW - CB chondrites

KW - Condensation

KW - Fe and Ni isotopes

KW - Impact plume

KW - Zoned metal

UR - http://www.scopus.com/inward/record.url?scp=85057623072&partnerID=8YFLogxK

U2 - 10.1016/j.gca.2018.11.022

DO - 10.1016/j.gca.2018.11.022

M3 - Article

AN - SCOPUS:85057623072

VL - 246

SP - 123

EP - 137

JO - Geochimica et cosmochimica acta

JF - Geochimica et cosmochimica acta

SN - 0016-7037

ER -

By the same author(s)