The vesiculated layer in the anomalous diogenite Northwest Africa 12973

Lidia Pittarello; Ludovic Ferrière; Stepan M. Chernonozhkin; Frank Vanhaecke; Steven Goderis

doi:10.1111/maps.14091

The vesiculated layer in the anomalous diogenite Northwest Africa 12973

Lidia Pittarello
, Ludovic Ferrière
, Stepan M. Chernonozhkin
, Frank Vanhaecke
, Steven Goderis

Department für Lithosphärenforschung

Veröffentlichungen: Beitrag in Fachzeitschrift › Artikel › Peer Reviewed

Abstract

Diogenites, which are part of the howardite–eucrite–diogenite (HED) group, are considered to represent rocks from the lower crust and mantle of a differentiated planetary body, likely the asteroid 4 Vesta. The Northwest Africa 12973 (NWA 12973) meteorite was classified as an anomalous diogenite due to the occurrence of a vesiculated layer. This work reports on the petrographic and geochemical study of two fragments of this meteorite, aiming to better constrain the origin of the vesiculated layer. Whereas the interior of NWA 12973 (here called host) presents the typical characteristics of an olivine diogenite, that is, coarse-grained pyroxene, olivine ribbons, chromite, and accessory phases, the vesiculated layer presents a fine-grained pyroxene groundmass with local rounded relics of olivine and interstitial chromite and metal, and is characterized by abundant large vesicles. The contact between the vesiculated layer and the host is sharply defined. The composition of individual minerals does not show any significant differences between the host and the vesiculated layer, suggesting in situ melting. Geothermobarometry indicates a slightly higher crystallization temperature at lower pressure for the vesiculated layer, consistent with melting and crystallization under lower crustal conditions upon exhumation. The trigger for the local melting was likely a large impact event, which was responsible for adiabatic decompression in the central area or deep faulting and frictional melting.

Originalsprache	Englisch
Seiten (von - bis)	1677-1690
Seitenumfang	14
Fachzeitschrift	Meteoritics and Planetary Science
Jahrgang	58
Ausgabenummer	11
DOIs	https://doi.org/10.1111/maps.14091
Publikationsstatus	Veröffentlicht - Nov. 2023

Fördermittel

We thank V. Jacques for providing the meteorite fragments investigated in this work and H. Goethals of the Royal Belgian Institute of Natural Sciences in Brussels (Belgium) for sharing his preliminary observations of another fragment of this meteorite. W. Wegner and D. Topa are thanked for assistance with the electron microprobe and G. Batic is thanked for sample preparation. S.M.Ch. acknowledges his postdoctoral fellowship from the Flemish Research Foundation (FWO) under the form of an “Excellence of Science (EoS)” project (ET-HoME—ID 30442502). F.V. and S.G. acknowledge the support from FWO under the form of the aforementioned EoS project and BOF-UGent. F.V. also acknowledges BOF-UGent and Teledyne CETAC Technologies for logistic and financial support. An anonymous reviewer and E. Jennings, and associate editor K. Joy are thanked for insightful comments, which contributed to improve the manuscript. We thank V. Jacques for providing the meteorite fragments investigated in this work and H. Goethals of the Royal Belgian Institute of Natural Sciences in Brussels (Belgium) for sharing his preliminary observations of another fragment of this meteorite. W. Wegner and D. Topa are thanked for assistance with the electron microprobe and G. Batic is thanked for sample preparation. S.M.Ch. acknowledges his postdoctoral fellowship from the Flemish Research Foundation (FWO) under the form of an “Excellence of Science (EoS)” project (ET‐HoME—ID 30442502). F.V. and S.G. acknowledge the support from FWO under the form of the aforementioned EoS project and BOF‐UGent. F.V. also acknowledges BOF‐UGent and Teledyne CETAC Technologies for logistic and financial support. An anonymous reviewer and E. Jennings, and associate editor K. Joy are thanked for insightful comments, which contributed to improve the manuscript.

ÖFOS 2012

105120 Petrologie
105105 Geochemie

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10.1111/maps.14091

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abstract = "Diogenites, which are part of the howardite–eucrite–diogenite (HED) group, are considered to represent rocks from the lower crust and mantle of a differentiated planetary body, likely the asteroid 4 Vesta. The Northwest Africa 12973 (NWA 12973) meteorite was classified as an anomalous diogenite due to the occurrence of a vesiculated layer. This work reports on the petrographic and geochemical study of two fragments of this meteorite, aiming to better constrain the origin of the vesiculated layer. Whereas the interior of NWA 12973 (here called host) presents the typical characteristics of an olivine diogenite, that is, coarse-grained pyroxene, olivine ribbons, chromite, and accessory phases, the vesiculated layer presents a fine-grained pyroxene groundmass with local rounded relics of olivine and interstitial chromite and metal, and is characterized by abundant large vesicles. The contact between the vesiculated layer and the host is sharply defined. The composition of individual minerals does not show any significant differences between the host and the vesiculated layer, suggesting in situ melting. Geothermobarometry indicates a slightly higher crystallization temperature at lower pressure for the vesiculated layer, consistent with melting and crystallization under lower crustal conditions upon exhumation. The trigger for the local melting was likely a large impact event, which was responsible for adiabatic decompression in the central area or deep faulting and frictional melting.",

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The vesiculated layer in the anomalous diogenite Northwest Africa 12973

Abstract

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ÖFOS 2012

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