In situ calibration of the Martian cratering chronology

Crater densities on planetary surfaces allow assessing relative ages but so far firm calibration of so‐called cratering‐chronology models is available only for the Moon and limited to the past 4.1 billion years. Most planetary geological time scales are still model‐dependent, and essentially constra...

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Veröffentlicht in:	Meteoritics & planetary science 2019-05, Vol.54 (5), p.1182-1193
1. Verfasser:	Werner, Stephanie C.
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Sprache:	eng
Schlagworte:	Age Calibration Chronology Curiosity (Mars rover) Geological time Lunar surface Mars Mars craters Mars rovers Mars satellites Migration Moon Planetary surfaces Planets Solar system Solar system evolution
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creator	Werner, Stephanie C.
description	Crater densities on planetary surfaces allow assessing relative ages but so far firm calibration of so‐called cratering‐chronology models is available only for the Moon and limited to the past 4.1 billion years. Most planetary geological time scales are still model‐dependent, and essentially constrained by meteorite ages or by comparison to (dynamical) solar system evolution models. Here we describe in situ calibration of the Martian cratering chronology using cosmogenic and radiogenic isotope ages obtained by the NASA Curiosity rover. We determined the cratering‐rate ratio between Moon and Mars for recent times, and extended the calibration of cratering rates to earlier times than those based exclusively on lunar data. Our preferred interpretation supports monotonic flux decay since at least 4.24 Ga and likely since about 4.45 Ga, implying orbital migration of the giant planets, and its direct, transient, dynamical effect on the planetesimal populations was initiated early. But only Martian Sample Return will provide strongly needed capability for distinction of the different models currently available.
doi_str_mv	10.1111/maps.13263
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subjects	Age Calibration Chronology Curiosity (Mars rover) Geological time Lunar surface Mars Mars craters Mars rovers Mars satellites Migration Moon Planetary surfaces Planets Solar system Solar system evolution
title	In situ calibration of the Martian cratering chronology
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