The Source Crater of Depleted Shergottites

Depleted shergottites record unique information about the primary composition and differentiation of the mantle of Mars. Their petrology, geochemistry, and cosmic ray exposure and crystallization ages suggest that most of them were excavated by a single young impact in the Amazonian‐aged lava flows...

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Veröffentlicht in:	Acta geologica Sinica (Beijing) 2024-12, Vol.98 (6), p.1672-1681
Hauptverfasser:	LUO, Fanglu, XIAO, Zhiyong, XU, Rui, CHANG, Yiren, MA, Yizhen, CAO, Wei, WU, Yunhua, WANG, Yichen
Format:	Artikel
Sprache:	eng
Schlagworte:	Age Cosmic radiation Cosmic rays crater chronology Crystallization depleted shergottites Depletion Ejecta Geochemistry impact crater impact cratering Impact melts Lava Lava flows Mars Mars craters Mars volcanoes Meteorite craters Meteors & meteorites Petrology Planetary geology Planetary mantles Shergottites SNC meteorites Subsurface water
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container_title	Acta geologica Sinica (Beijing)
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creator	LUO, Fanglu XIAO, Zhiyong XU, Rui CHANG, Yiren MA, Yizhen CAO, Wei WU, Yunhua WANG, Yichen
description	Depleted shergottites record unique information about the primary composition and differentiation of the mantle of Mars. Their petrology, geochemistry, and cosmic ray exposure and crystallization ages suggest that most of them were excavated by a single young impact in the Amazonian‐aged lava flows of the Tharsis and Elysium volcanic provinces. However, the difficulties of deriving consistent model ages for individual craters and inadequate evaluation of 3–7 km craters capable of ejecting martian meteorites have not been settled. Here we perform detailed geological investigations and crater statistics in patches of impact melt deposits for potential source craters of depleted shergottites with D > 3 km, especially those in the Tharsis and Elysium volcanic provinces. By excluding the effect of heterogeneous textures across ejecta deposits, which hinder straightforward extraction of superposed production populations, our systematically updated model ages reveal that Chakpar crater at the northern flank of Ascraeus Mons is the best‐fit candidate. The local context of this crater permits establishing a link between the meteorites and specific lava flows. The long‐lived volcanic center here may experience an eruption and/or local deposition hiatus for about 1.8 billion years, and abundant subsurface water existed when the impact occurred at about 1.1 million years.
doi_str_mv	10.1111/1755-6724.15189
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The local context of this crater permits establishing a link between the meteorites and specific lava flows. 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subjects	Age Cosmic radiation Cosmic rays crater chronology Crystallization depleted shergottites Depletion Ejecta Geochemistry impact crater impact cratering Impact melts Lava Lava flows Mars Mars craters Mars volcanoes Meteorite craters Meteors & meteorites Petrology Planetary geology Planetary mantles Shergottites SNC meteorites Subsurface water
title	The Source Crater of Depleted Shergottites
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