The parent bodies of CR chondrites and their secondary history

Trygve Prestgard; Pierre Beck; Lydie Bonal; Jolantha Eschrig; Jérôme Gattacceca; Corinne Sonzogni; Lisa Krämer Ruggiu

doi:10.1111/maps.14048

The parent bodies of CR chondrites and their secondary history

Trygve Prestgard, Pierre Beck, Lydie Bonal, Jolantha Eschrig, Jérôme Gattacceca, Corinne Sonzogni, Lisa Krämer Ruggiu

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Abstract

Renazzo-type (CR) chondrites are a relatively rare group of carbonaceous chondrites with the vast majority having escaped thermal alteration (e.g., Schrader et al., 2015). This means that CRs are composed of relatively unprocessed material, depending on the extent of aqueous alteration they have experienced. Hydration in CRs ranges from incipient alteration of matrix glass, up to nearly complete replacement of the rock by hydration products. The extent of secondary processes is often difficult to assess in these meteorites, due to their heterogeneity and diversity of alteration products. Yet, this is crucial in order to understand the extent of geological processing that occurred on the primary parent body. Additionally, the parent asteroids of CRs remain a mystery, mainly because terrestrial oxyhydroxide signatures dominate the reflectance spectra of CRs. In this work, we have conducted optical and IR reflectance and transmission spectra of 25 CR chondrites in order to (i) better evaluate the extent of aqueous alteration that occurred on the CR parent body, and (ii) find possible parent body candidates. Terrestrial oxyhydroxides were removed from twelve samples, as these tend to interfere with the optical-IR spectra of CRs. Our results suggest, among other, that (i) aqueous alteration in most of our CRs was limited to the matrix and (ii) most CRs may stem from a continuum of X-to-C complex asteroids, depending on their extent of aqueous alteration. More specifically, the end members being Xk/Xn-types and Cgh/Ch-types. This has strong implication in regards to what we can expect from the Psyche mission.

Original language	English
Pages (from-to)	1117-1148
Number of pages	32
Journal	Meteoritics & Planetary Science
Volume	58
Issue number	8
DOIs	https://doi.org/10.1111/maps.14048
Publication status	Published - Aug 2023

Bibliographical note

Funding Information:
We wish to thank ANSMET, CEREGE, and the Museo di Storia Naturale Università degli Studi di Firenze, for providing the meteorites that made this study possible. The SR-μFTIR experiment of LAP 02342 was performed at MIRAS beamline at ALBA Synchrotron with the collaboration of ALBA staff. We also wish to thank Dr. Eric Quirico, Dr. Rolando Rebois, and Dr. Thai Van Phan for their help during this mission. We also wish to thank Edward Cloutis for the editorial handling, as well as the reviewers for their constructive and insightful comments. The mission was funded by the CNES. This work was funded by the European Research Council under the H2020 framework program/ERC grant agreement no. 771691(Solarys).

Funding Information:
We wish to thank ANSMET, CEREGE, and the Museo di Storia Naturale Università degli Studi di Firenze, for providing the meteorites that made this study possible. The SR‐μFTIR experiment of LAP 02342 was performed at MIRAS beamline at ALBA Synchrotron with the collaboration of ALBA staff. We also wish to thank Dr. Eric Quirico, Dr. Rolando Rebois, and Dr. Thai Van Phan for their help during this mission. We also wish to thank Edward Cloutis for the editorial handling, as well as the reviewers for their constructive and insightful comments. The mission was funded by the CNES. This work was funded by the European Research Council under the H2020 framework program/ERC grant agreement no. 771691(Solarys).

Publisher Copyright:
© 2023 The Authors. Meteoritics & Planetary Science published by Wiley Periodicals LLC on behalf of The Meteoritical Society.

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10.1111/maps.14048

20230620_Revised_Prestgard_Main_Document_CR_Chondrites_MAPS3809Licence: Other

Cite this

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title = "The parent bodies of CR chondrites and their secondary history",

abstract = "Renazzo-type (CR) chondrites are a relatively rare group of carbonaceous chondrites with the vast majority having escaped thermal alteration (e.g., Schrader et al., 2015). This means that CRs are composed of relatively unprocessed material, depending on the extent of aqueous alteration they have experienced. Hydration in CRs ranges from incipient alteration of matrix glass, up to nearly complete replacement of the rock by hydration products. The extent of secondary processes is often difficult to assess in these meteorites, due to their heterogeneity and diversity of alteration products. Yet, this is crucial in order to understand the extent of geological processing that occurred on the primary parent body. Additionally, the parent asteroids of CRs remain a mystery, mainly because terrestrial oxyhydroxide signatures dominate the reflectance spectra of CRs. In this work, we have conducted optical and IR reflectance and transmission spectra of 25 CR chondrites in order to (i) better evaluate the extent of aqueous alteration that occurred on the CR parent body, and (ii) find possible parent body candidates. Terrestrial oxyhydroxides were removed from twelve samples, as these tend to interfere with the optical-IR spectra of CRs. Our results suggest, among other, that (i) aqueous alteration in most of our CRs was limited to the matrix and (ii) most CRs may stem from a continuum of X-to-C complex asteroids, depending on their extent of aqueous alteration. More specifically, the end members being Xk/Xn-types and Cgh/Ch-types. This has strong implication in regards to what we can expect from the Psyche mission.",

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note = "Funding Information: We wish to thank ANSMET, CEREGE, and the Museo di Storia Naturale Universit{\`a} degli Studi di Firenze, for providing the meteorites that made this study possible. The SR-μFTIR experiment of LAP 02342 was performed at MIRAS beamline at ALBA Synchrotron with the collaboration of ALBA staff. We also wish to thank Dr. Eric Quirico, Dr. Rolando Rebois, and Dr. Thai Van Phan for their help during this mission. We also wish to thank Edward Cloutis for the editorial handling, as well as the reviewers for their constructive and insightful comments. The mission was funded by the CNES. This work was funded by the European Research Council under the H2020 framework program/ERC grant agreement no. 771691(Solarys). Funding Information: We wish to thank ANSMET, CEREGE, and the Museo di Storia Naturale Universit{\`a} degli Studi di Firenze, for providing the meteorites that made this study possible. The SR‐μFTIR experiment of LAP 02342 was performed at MIRAS beamline at ALBA Synchrotron with the collaboration of ALBA staff. We also wish to thank Dr. Eric Quirico, Dr. Rolando Rebois, and Dr. Thai Van Phan for their help during this mission. We also wish to thank Edward Cloutis for the editorial handling, as well as the reviewers for their constructive and insightful comments. The mission was funded by the CNES. This work was funded by the European Research Council under the H2020 framework program/ERC grant agreement no. 771691(Solarys). Publisher Copyright: {\textcopyright} 2023 The Authors. Meteoritics & Planetary Science published by Wiley Periodicals LLC on behalf of The Meteoritical Society.",

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N2 - Renazzo-type (CR) chondrites are a relatively rare group of carbonaceous chondrites with the vast majority having escaped thermal alteration (e.g., Schrader et al., 2015). This means that CRs are composed of relatively unprocessed material, depending on the extent of aqueous alteration they have experienced. Hydration in CRs ranges from incipient alteration of matrix glass, up to nearly complete replacement of the rock by hydration products. The extent of secondary processes is often difficult to assess in these meteorites, due to their heterogeneity and diversity of alteration products. Yet, this is crucial in order to understand the extent of geological processing that occurred on the primary parent body. Additionally, the parent asteroids of CRs remain a mystery, mainly because terrestrial oxyhydroxide signatures dominate the reflectance spectra of CRs. In this work, we have conducted optical and IR reflectance and transmission spectra of 25 CR chondrites in order to (i) better evaluate the extent of aqueous alteration that occurred on the CR parent body, and (ii) find possible parent body candidates. Terrestrial oxyhydroxides were removed from twelve samples, as these tend to interfere with the optical-IR spectra of CRs. Our results suggest, among other, that (i) aqueous alteration in most of our CRs was limited to the matrix and (ii) most CRs may stem from a continuum of X-to-C complex asteroids, depending on their extent of aqueous alteration. More specifically, the end members being Xk/Xn-types and Cgh/Ch-types. This has strong implication in regards to what we can expect from the Psyche mission.

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The parent bodies of CR chondrites and their secondary history

Abstract

Bibliographical note

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SRP68: SRP-Onderzoekszwaartepunt: Earth: from Accretion to Anthropocene: Documenting 4.5 Billion Years of Global Changes

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The parent bodies of CR chondrites and their secondary history

Abstract

Bibliographical note

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SRP68: SRP-Onderzoekszwaartepunt: Earth: from Accretion to Anthropocene: Documenting 4.5 Billion Years of Global Changes

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