Extensive and ancient feldspathic crust detected across north Hellas rim, Mars: Possible implications for primary crust formation

Michael S. Phillips; Christina E. Viviano; Jeffrey E. Moersch; A. Deanne Rogers; Harry Y. McSween; Frank P. Seelos

doi:10.1130/G50341.1

Extensive and ancient feldspathic crust detected across north Hellas rim, Mars: Possible implications for primary crust formation

Michael S. Phillips
, Christina E. Viviano
, Jeffrey E. Moersch
, A. Deanne Rogers
, Harry Y. McSween
, Frank P. Seelos

Geosciences

Johns Hopkins University Applied Physics Laboratory
University of Tennessee

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

18 Scopus citations

Abstract

Due to its size and observable record of ancient rock, Mars is key to understanding crustal formation on planetary bodies, including Venus and Earth, which may have derived their first stable crust from mantle-overturn melting. Recent evidence that ancient martian crust contains an evolved component supports inferences of a pervasive, buried feldspathic component to the crust. With data from the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), we searched for feldspathic lithologies in pre-Noachian (older than ca. 4.1 Ga) crustal blocks uplifted by the Hellas basin-forming impact. We present evidence for ancient feldspathic rocks exposed across an ~2200 × 600 km area north of Hellas. Given their pre-Noachian age and stratigraphic position directly above putative mantle material, it is possible that these outcrops represent martian primary crust.

Original language	English
Pages (from-to)	1182-1186
Number of pages	5
Journal	Geology
Volume	50
Issue number	10
DOIs	https://doi.org/10.1130/G50341.1
State	Published - Oct 2022

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abstract = "Due to its size and observable record of ancient rock, Mars is key to understanding crustal formation on planetary bodies, including Venus and Earth, which may have derived their first stable crust from mantle-overturn melting. Recent evidence that ancient martian crust contains an evolved component supports inferences of a pervasive, buried feldspathic component to the crust. With data from the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), we searched for feldspathic lithologies in pre-Noachian (older than ca. 4.1 Ga) crustal blocks uplifted by the Hellas basin-forming impact. We present evidence for ancient feldspathic rocks exposed across an \textasciitilde{}2200 × 600 km area north of Hellas. Given their pre-Noachian age and stratigraphic position directly above putative mantle material, it is possible that these outcrops represent martian primary crust.",

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doi = "10.1130/G50341.1",

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T2 - Possible implications for primary crust formation

AU - Phillips, Michael S.

AU - Viviano, Christina E.

AU - Moersch, Jeffrey E.

AU - Rogers, A. Deanne

AU - McSween, Harry Y.

AU - Seelos, Frank P.

PY - 2022/10

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N2 - Due to its size and observable record of ancient rock, Mars is key to understanding crustal formation on planetary bodies, including Venus and Earth, which may have derived their first stable crust from mantle-overturn melting. Recent evidence that ancient martian crust contains an evolved component supports inferences of a pervasive, buried feldspathic component to the crust. With data from the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), we searched for feldspathic lithologies in pre-Noachian (older than ca. 4.1 Ga) crustal blocks uplifted by the Hellas basin-forming impact. We present evidence for ancient feldspathic rocks exposed across an ~2200 × 600 km area north of Hellas. Given their pre-Noachian age and stratigraphic position directly above putative mantle material, it is possible that these outcrops represent martian primary crust.

AB - Due to its size and observable record of ancient rock, Mars is key to understanding crustal formation on planetary bodies, including Venus and Earth, which may have derived their first stable crust from mantle-overturn melting. Recent evidence that ancient martian crust contains an evolved component supports inferences of a pervasive, buried feldspathic component to the crust. With data from the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), we searched for feldspathic lithologies in pre-Noachian (older than ca. 4.1 Ga) crustal blocks uplifted by the Hellas basin-forming impact. We present evidence for ancient feldspathic rocks exposed across an ~2200 × 600 km area north of Hellas. Given their pre-Noachian age and stratigraphic position directly above putative mantle material, it is possible that these outcrops represent martian primary crust.

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U2 - 10.1130/G50341.1

DO - 10.1130/G50341.1

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Extensive and ancient feldspathic crust detected across north Hellas rim, Mars: Possible implications for primary crust formation

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