Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits. / Van Maldeghem, Flore; Maeda, Ryoga; Soens, Bastien; Suttle, Martin D.; Ruggiu, Lisa Krämer; Cordier, Carole; Yamaguchi, Akira; Schmitz, Birger; Claeys, Philippe; Folco, Luigi; Goderis, Steven.

In: Earth and Planetary Science Letters, Vol. 641, 118837, 2024.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Van Maldeghem, F, Maeda, R, Soens, B, Suttle, MD, Ruggiu, LK, Cordier, C, Yamaguchi, A, Schmitz, B, Claeys, P, Folco, L & Goderis, S 2024, 'Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits', Earth and Planetary Science Letters, vol. 641, 118837. https://doi.org/10.1016/j.epsl.2024.118837

APA

Van Maldeghem, F., Maeda, R., Soens, B., Suttle, M. D., Ruggiu, L. K., Cordier, C., Yamaguchi, A., Schmitz, B., Claeys, P., Folco, L., & Goderis, S. (2024). Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits. Earth and Planetary Science Letters, 641, [118837]. https://doi.org/10.1016/j.epsl.2024.118837

Vancouver

Van Maldeghem F, Maeda R, Soens B, Suttle MD, Ruggiu LK, Cordier C et al. Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits. Earth and Planetary Science Letters. 2024;641. 118837. https://doi.org/10.1016/j.epsl.2024.118837

Author

Van Maldeghem, Flore ; Maeda, Ryoga ; Soens, Bastien ; Suttle, Martin D. ; Ruggiu, Lisa Krämer ; Cordier, Carole ; Yamaguchi, Akira ; Schmitz, Birger ; Claeys, Philippe ; Folco, Luigi ; Goderis, Steven. / Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits. In: Earth and Planetary Science Letters. 2024 ; Vol. 641.

Bibtex

@article{b76bd03e1f7e4e5b84094bff368bc74a,
title = "Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits",
abstract = "Each year, approximately 5000 tons of extraterrestrial material reaches the Earth's surface as micrometeorites, cosmic dust particles ranging from 10 to 2000 μm in size. These micrometeorites, collected from diverse environments, mainly deep-sea sediments, Antarctic ice, snow and loose sediments, and hot deserts, are crucial in understanding our Solar System's evolution. Chrome-rich spinel (Cr-spinel) minerals have gained attention as proxies for studying the extraterrestrial flux in sedimentary deposits, because these robust minerals occur, in various extraterrestrial materials, with compositions characteristic of their parent bodies. A total of 27 Cr-spinel bearing micrometeorites within the size range of 185–800 μm, were identified from approximately 6000 micrometeorites from the Transantarctic Mountains (n = 23) and the S{\o}r Rondane Mountains (n = 4), in Antarctica, containing Cr-spinel (8–120 μm), were examined in this study for geochemical composition and high-precision oxygen isotope ratios to assess alteration and identify potential parent bodies. Oxygen isotopes in the micrometeorite groundmass and in Cr-spinel grains reveal a predominance of ordinary chondritic precursors, with only 1 in 10 micrometeorites containing Cr-spinel minerals showing a carbonaceous chondritic signature. This may be further confirmed by an elevated Al content (> 12 wt% Al2O3) in Cr-spinel from specific carbonaceous chondrite types, but a more extensive dataset is required to establish definitive criteria. The first Cr-spinel bearing particle, in an Antarctic micrometeorite, that can be linked to R-chondrites based on oxygen isotopes, has been documented, demonstrating the potential for R-chondrites as a source of chrome-rich spinels. The study also highlights the potential for chemical modifications and alteration processes that Cr-spinel minerals may undergo during their time on the parent body, atmospheric entry, and terrestrial residence. In the context of the broader micrometeorite flux, the results align with previous findings, showing a consistent contribution of micrometeorites containing Cr-spinel minerals related to ordinary chondrites over the past 2 to 4 million years. This is however a small fraction (∼ 1 %) of the total micrometeorite flux. The study further confirms that Cr-spinel minerals recovered from sedimentary deposits serve as valuable proxies for tracking events related to ordinary chondritic or achondritic materials. However, it is emphasized that Cr-spinel minerals alone cannot serve as exclusive indicators of the overall extraterrestrial flux, especially during periods dominated by carbonaceous chondritic dust in the inner Solar System. To comprehensively understand the complete extraterrestrial flux, additional proxies are needed to trace dust-producing events associated with various Solar System objects. The intricate nature of Cr-spinel compositions, and the potential for alteration processes emphasize the need for further research to refine our understanding of these extraterrestrial markers.",
keywords = "Chromite, Cosmic spherules, Cr-spinel, Micrometeorites, Oxygen isotope ratios, Parent bodies",
author = "{Van Maldeghem}, Flore and Ryoga Maeda and Bastien Soens and Suttle, {Martin D.} and Ruggiu, {Lisa Kr{\"a}mer} and Carole Cordier and Akira Yamaguchi and Birger Schmitz and Philippe Claeys and Luigi Folco and Steven Goderis",
note = "Publisher Copyright: {\textcopyright} 2024",
year = "2024",
doi = "10.1016/j.epsl.2024.118837",
language = "English",
volume = "641",
journal = "Earth and Planetary Science Letters",
issn = "0012-821X",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Chrome-rich spinels in micrometeorites from modern Antarctic sedimentary deposits

AU - Van Maldeghem, Flore

AU - Maeda, Ryoga

AU - Soens, Bastien

AU - Suttle, Martin D.

AU - Ruggiu, Lisa Krämer

AU - Cordier, Carole

AU - Yamaguchi, Akira

AU - Schmitz, Birger

AU - Claeys, Philippe

AU - Folco, Luigi

AU - Goderis, Steven

N1 - Publisher Copyright: © 2024

PY - 2024

Y1 - 2024

N2 - Each year, approximately 5000 tons of extraterrestrial material reaches the Earth's surface as micrometeorites, cosmic dust particles ranging from 10 to 2000 μm in size. These micrometeorites, collected from diverse environments, mainly deep-sea sediments, Antarctic ice, snow and loose sediments, and hot deserts, are crucial in understanding our Solar System's evolution. Chrome-rich spinel (Cr-spinel) minerals have gained attention as proxies for studying the extraterrestrial flux in sedimentary deposits, because these robust minerals occur, in various extraterrestrial materials, with compositions characteristic of their parent bodies. A total of 27 Cr-spinel bearing micrometeorites within the size range of 185–800 μm, were identified from approximately 6000 micrometeorites from the Transantarctic Mountains (n = 23) and the Sør Rondane Mountains (n = 4), in Antarctica, containing Cr-spinel (8–120 μm), were examined in this study for geochemical composition and high-precision oxygen isotope ratios to assess alteration and identify potential parent bodies. Oxygen isotopes in the micrometeorite groundmass and in Cr-spinel grains reveal a predominance of ordinary chondritic precursors, with only 1 in 10 micrometeorites containing Cr-spinel minerals showing a carbonaceous chondritic signature. This may be further confirmed by an elevated Al content (> 12 wt% Al2O3) in Cr-spinel from specific carbonaceous chondrite types, but a more extensive dataset is required to establish definitive criteria. The first Cr-spinel bearing particle, in an Antarctic micrometeorite, that can be linked to R-chondrites based on oxygen isotopes, has been documented, demonstrating the potential for R-chondrites as a source of chrome-rich spinels. The study also highlights the potential for chemical modifications and alteration processes that Cr-spinel minerals may undergo during their time on the parent body, atmospheric entry, and terrestrial residence. In the context of the broader micrometeorite flux, the results align with previous findings, showing a consistent contribution of micrometeorites containing Cr-spinel minerals related to ordinary chondrites over the past 2 to 4 million years. This is however a small fraction (∼ 1 %) of the total micrometeorite flux. The study further confirms that Cr-spinel minerals recovered from sedimentary deposits serve as valuable proxies for tracking events related to ordinary chondritic or achondritic materials. However, it is emphasized that Cr-spinel minerals alone cannot serve as exclusive indicators of the overall extraterrestrial flux, especially during periods dominated by carbonaceous chondritic dust in the inner Solar System. To comprehensively understand the complete extraterrestrial flux, additional proxies are needed to trace dust-producing events associated with various Solar System objects. The intricate nature of Cr-spinel compositions, and the potential for alteration processes emphasize the need for further research to refine our understanding of these extraterrestrial markers.

AB - Each year, approximately 5000 tons of extraterrestrial material reaches the Earth's surface as micrometeorites, cosmic dust particles ranging from 10 to 2000 μm in size. These micrometeorites, collected from diverse environments, mainly deep-sea sediments, Antarctic ice, snow and loose sediments, and hot deserts, are crucial in understanding our Solar System's evolution. Chrome-rich spinel (Cr-spinel) minerals have gained attention as proxies for studying the extraterrestrial flux in sedimentary deposits, because these robust minerals occur, in various extraterrestrial materials, with compositions characteristic of their parent bodies. A total of 27 Cr-spinel bearing micrometeorites within the size range of 185–800 μm, were identified from approximately 6000 micrometeorites from the Transantarctic Mountains (n = 23) and the Sør Rondane Mountains (n = 4), in Antarctica, containing Cr-spinel (8–120 μm), were examined in this study for geochemical composition and high-precision oxygen isotope ratios to assess alteration and identify potential parent bodies. Oxygen isotopes in the micrometeorite groundmass and in Cr-spinel grains reveal a predominance of ordinary chondritic precursors, with only 1 in 10 micrometeorites containing Cr-spinel minerals showing a carbonaceous chondritic signature. This may be further confirmed by an elevated Al content (> 12 wt% Al2O3) in Cr-spinel from specific carbonaceous chondrite types, but a more extensive dataset is required to establish definitive criteria. The first Cr-spinel bearing particle, in an Antarctic micrometeorite, that can be linked to R-chondrites based on oxygen isotopes, has been documented, demonstrating the potential for R-chondrites as a source of chrome-rich spinels. The study also highlights the potential for chemical modifications and alteration processes that Cr-spinel minerals may undergo during their time on the parent body, atmospheric entry, and terrestrial residence. In the context of the broader micrometeorite flux, the results align with previous findings, showing a consistent contribution of micrometeorites containing Cr-spinel minerals related to ordinary chondrites over the past 2 to 4 million years. This is however a small fraction (∼ 1 %) of the total micrometeorite flux. The study further confirms that Cr-spinel minerals recovered from sedimentary deposits serve as valuable proxies for tracking events related to ordinary chondritic or achondritic materials. However, it is emphasized that Cr-spinel minerals alone cannot serve as exclusive indicators of the overall extraterrestrial flux, especially during periods dominated by carbonaceous chondritic dust in the inner Solar System. To comprehensively understand the complete extraterrestrial flux, additional proxies are needed to trace dust-producing events associated with various Solar System objects. The intricate nature of Cr-spinel compositions, and the potential for alteration processes emphasize the need for further research to refine our understanding of these extraterrestrial markers.

KW - Chromite

KW - Cosmic spherules

KW - Cr-spinel

KW - Micrometeorites

KW - Oxygen isotope ratios

KW - Parent bodies

U2 - 10.1016/j.epsl.2024.118837

DO - 10.1016/j.epsl.2024.118837

M3 - Journal article

AN - SCOPUS:85196044565

VL - 641

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

SN - 0012-821X

M1 - 118837

ER -

ID: 398077587