Parent body thermal metamorphism of enstatite chondrites: Disentangling the effects of shock melting

Peter Mc Ardle; Rhian H. Jones; Patricia L. Clay; Romain Tartese; Ray Burgess; Brian O'driscoll; Eric W. G. Hellebrand; Jonathan Fellowes; Arthur Goodwin; Lewis Hughes

doi:10.1111/maps.70065

Parent body thermal metamorphism of enstatite chondrites: Disentangling the effects of shock melting

Peter Mc Ardle^*
, Rhian H. Jones
, Patricia L. Clay
, Romain Tartese
, Ray Burgess
, Brian O'driscoll
, Eric W. G. Hellebrand
, Jonathan Fellowes
, Arthur Goodwin
, Lewis Hughes

^*Corresponding author for this work

University of Manchester
University of Ottawa

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

Abstract

Enstatite chondrites (ECs) formed on at least two parent bodies, EH and EL. After the accretion of the EC parent bodies, EC material was subjected to varying degrees of parent body thermal metamorphism (measured by petrologic types 3–6), due to heat released by radioactive isotope decay. Current schemes to determine the petrologic type of the ECs are qualitative and ambiguous, and many studies have included known or misclassified shock-melted ECs, which altogether have led to inconsistent classifications. In this study, we attempt to distinguish shock-melted ECs from other ECs so that we can assess the effects of thermal metamorphism alone. We identified a suite of geochemical parameters that allow us to classify rapidly cooled, quenched shock-melt ECs, including high-Fe (Mg,Mn,Fe)S monosulfide, high-Cr troilite, and high-Ni kamacite. We then screened out shock-melted samples. This then allowed us to establish a quantitative scheme to determine the petrologic type of an EC. This classification scheme is based on the petrography and geochemistry of glass, silicate minerals, sulfides, and metal. Specifically, for EH chondrites (which are similar but distinct from the EL group), among other parameters, the size and abundance of feldspar progressively increase from EH3 to EH6 (<13 μm, <8.5% modal% to >13 μm, 11.5 modal%), while the FeO content of enstatite changes from types 3–4 to types 5–6 (<0.45 wt% to >0.45 wt%). Additionally, we build on the work of others to propose a scheme that subdivides the EH3. Using the average Cr₂O₃ content of olivine, we divide the EH3 and EH4 chondrites into EH3_Low (mean Cr₂O₃ > 0.25 wt%) and EH3_High-EH4 subtypes (Cr₂O₃ < 0.25 wt%).

Original language	English
Pages (from-to)	2828-2863
Number of pages	36
Journal	Meteoritics and Planetary Science
Volume	60
Issue number	12
Early online date	4 Nov 2025
DOIs	https://doi.org/10.1111/maps.70065
Publication status	Published - Dec 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Meteoritics & Planetary Science published by Wiley Periodicals LLC on behalf of The Meteoritical Society.

Funding

We thank Oliver Plümper for his support in securing funding for EPMA access through the EXCITE Network. We thank the various meteorite hunters/dealers/collectors for sourcing the samples included in this study. We thank the classifiers for working on these samples. We thank the following individuals and institutions for providing samples: The Antarctic Search for Meteorites/NASA/JSC, National Institute for Polar Research, University of California Los Angeles Meteorite Collection, F. Kuntz (WW Meteorites), E. Twelker (The Meteorite Market), Natural History Museum London, Chicago Field Museum, Senckenberg Institute, S. Tutorow (Eegooblago Meteorites), Bartoschewitz Meteorite Laboratory, Museo del Cielo e della Terra di San Giovanni Persiceto, T. Irving (University of Washington, Seattle), Museum National d'Histoire Naturelle Paris, and M. Farmer (Michael Farmer Meteorites). We thank Ed Baker for the SEM‐EDS maps of EET 83322. This project has received funding from the European Union's Horizon 2020 research and innovation program under grant agreement no.: 101005611 for Transnational Access conducted at Utrecht University. Brian O'Driscoll acknowledges current research support from the Natural Sciences and Engineering Research Council of Canada (NSERC Discovery Grant) and from the Newmont Chair in Economic Geology (University of Ottawa). RHJ acknowledges support from the UK Science and Technology Facilities Council (STFC) grant ST/V000675/1.

Funders	Funder number
Natural Sciences and Engineering Research Council of Canada
Horizon 2020 Framework Programme	101005611
Science and Technology Facilities Council	ST/V000675/1

Keywords

Ages
Classification
Diopside
El
History
Metal
Meteorite
Origin
Qingzhen eh3
Raman-spectroscopy

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Meteorit Planetary Scien - 2025 - Ardle - Parent body thermal metamorphism of enstatite chondrites Disentangling theFinal published version, 5.02 MBLicence: CC BY

Cite this

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title = "Parent body thermal metamorphism of enstatite chondrites: Disentangling the effects of shock melting",

abstract = "Enstatite chondrites (ECs) formed on at least two parent bodies, EH and EL. After the accretion of the EC parent bodies, EC material was subjected to varying degrees of parent body thermal metamorphism (measured by petrologic types 3–6), due to heat released by radioactive isotope decay. Current schemes to determine the petrologic type of the ECs are qualitative and ambiguous, and many studies have included known or misclassified shock-melted ECs, which altogether have led to inconsistent classifications. In this study, we attempt to distinguish shock-melted ECs from other ECs so that we can assess the effects of thermal metamorphism alone. We identified a suite of geochemical parameters that allow us to classify rapidly cooled, quenched shock-melt ECs, including high-Fe (Mg,Mn,Fe)S monosulfide, high-Cr troilite, and high-Ni kamacite. We then screened out shock-melted samples. This then allowed us to establish a quantitative scheme to determine the petrologic type of an EC. This classification scheme is based on the petrography and geochemistry of glass, silicate minerals, sulfides, and metal. Specifically, for EH chondrites (which are similar but distinct from the EL group), among other parameters, the size and abundance of feldspar progressively increase from EH3 to EH6 (<13 μm, <8.5\% modal\% to >13 μm, 11.5 modal\%), while the FeO content of enstatite changes from types 3–4 to types 5–6 (<0.45 wt\% to >0.45 wt\%). Additionally, we build on the work of others to propose a scheme that subdivides the EH3. Using the average Cr2O3 content of olivine, we divide the EH3 and EH4 chondrites into EH3Low (mean Cr2O3 > 0.25 wt\%) and EH3High-EH4 subtypes (Cr2O3 < 0.25 wt\%).",

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note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Meteoritics \& Planetary Science published by Wiley Periodicals LLC on behalf of The Meteoritical Society.",

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doi = "10.1111/maps.70065",

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T2 - Disentangling the effects of shock melting

AU - Mc Ardle, Peter

AU - Jones, Rhian H.

AU - Clay, Patricia L.

AU - Tartese, Romain

AU - Burgess, Ray

AU - O'driscoll, Brian

AU - Hellebrand, Eric W. G.

AU - Fellowes, Jonathan

AU - Goodwin, Arthur

AU - Hughes, Lewis

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N2 - Enstatite chondrites (ECs) formed on at least two parent bodies, EH and EL. After the accretion of the EC parent bodies, EC material was subjected to varying degrees of parent body thermal metamorphism (measured by petrologic types 3–6), due to heat released by radioactive isotope decay. Current schemes to determine the petrologic type of the ECs are qualitative and ambiguous, and many studies have included known or misclassified shock-melted ECs, which altogether have led to inconsistent classifications. In this study, we attempt to distinguish shock-melted ECs from other ECs so that we can assess the effects of thermal metamorphism alone. We identified a suite of geochemical parameters that allow us to classify rapidly cooled, quenched shock-melt ECs, including high-Fe (Mg,Mn,Fe)S monosulfide, high-Cr troilite, and high-Ni kamacite. We then screened out shock-melted samples. This then allowed us to establish a quantitative scheme to determine the petrologic type of an EC. This classification scheme is based on the petrography and geochemistry of glass, silicate minerals, sulfides, and metal. Specifically, for EH chondrites (which are similar but distinct from the EL group), among other parameters, the size and abundance of feldspar progressively increase from EH3 to EH6 (<13 μm, <8.5% modal% to >13 μm, 11.5 modal%), while the FeO content of enstatite changes from types 3–4 to types 5–6 (<0.45 wt% to >0.45 wt%). Additionally, we build on the work of others to propose a scheme that subdivides the EH3. Using the average Cr2O3 content of olivine, we divide the EH3 and EH4 chondrites into EH3Low (mean Cr2O3 > 0.25 wt%) and EH3High-EH4 subtypes (Cr2O3 < 0.25 wt%).

AB - Enstatite chondrites (ECs) formed on at least two parent bodies, EH and EL. After the accretion of the EC parent bodies, EC material was subjected to varying degrees of parent body thermal metamorphism (measured by petrologic types 3–6), due to heat released by radioactive isotope decay. Current schemes to determine the petrologic type of the ECs are qualitative and ambiguous, and many studies have included known or misclassified shock-melted ECs, which altogether have led to inconsistent classifications. In this study, we attempt to distinguish shock-melted ECs from other ECs so that we can assess the effects of thermal metamorphism alone. We identified a suite of geochemical parameters that allow us to classify rapidly cooled, quenched shock-melt ECs, including high-Fe (Mg,Mn,Fe)S monosulfide, high-Cr troilite, and high-Ni kamacite. We then screened out shock-melted samples. This then allowed us to establish a quantitative scheme to determine the petrologic type of an EC. This classification scheme is based on the petrography and geochemistry of glass, silicate minerals, sulfides, and metal. Specifically, for EH chondrites (which are similar but distinct from the EL group), among other parameters, the size and abundance of feldspar progressively increase from EH3 to EH6 (<13 μm, <8.5% modal% to >13 μm, 11.5 modal%), while the FeO content of enstatite changes from types 3–4 to types 5–6 (<0.45 wt% to >0.45 wt%). Additionally, we build on the work of others to propose a scheme that subdivides the EH3. Using the average Cr2O3 content of olivine, we divide the EH3 and EH4 chondrites into EH3Low (mean Cr2O3 > 0.25 wt%) and EH3High-EH4 subtypes (Cr2O3 < 0.25 wt%).

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Parent body thermal metamorphism of enstatite chondrites: Disentangling the effects of shock melting

Abstract

Bibliographical note

Funding

Keywords

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