Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?

Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?

The impact flux over the last 3 Ga in the inner Solar System is commonly assumed to be constant through time due to insufficient data to warrant a different choice for this range of time. However, asteroid break-up events in the main belt may have been responsible for cratering spikes over the last...

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Main Authors: Lagain, Anthony, Kreslavsky, M., Baratoux, D., Liu, Yebo, Devillepoix, Hadrien, Bland, Philip, Benedix, Gretchen, Doucet, Luc, Servis, K.
Format: Journal Article
Language:English
Published: ELSEVIER 2022
Subjects:
Science & Technology
Physical Sciences
Geochemistry & Geophysics
impact flux
craters
automatic crater detection
inner Solar System
CRATER
AGES
BOMBARDMENT
CHRONOLOGY
HISTORY
Online Access:http://purl.org/au-research/grants/arc/DP170102972
http://hdl.handle.net/20.500.11937/90798
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author Lagain, Anthony
Kreslavsky, M.
Baratoux, D.
Liu, Yebo
Devillepoix, Hadrien
Bland, Philip
Benedix, Gretchen
Doucet, Luc
Servis, K.
author_facet Lagain, Anthony
Kreslavsky, M.
Baratoux, D.
Liu, Yebo
Devillepoix, Hadrien
Bland, Philip
Benedix, Gretchen
Doucet, Luc
Servis, K.
author_sort Lagain, Anthony
building Curtin Institutional Repository
collection Online Access
description The impact flux over the last 3 Ga in the inner Solar System is commonly assumed to be constant through time due to insufficient data to warrant a different choice for this range of time. However, asteroid break-up events in the main belt may have been responsible for cratering spikes over the last ∼2 Ga on the Earth-Moon system. Due to its proximity with the main asteroid belt, i.e., the main impactors reservoir, Mars is at the outpost of these events with respect to the other inner planets. We investigate here, from automatic crater identification, the possible variations of the size frequency distributions of impactors from the record of small craters of 521 impact craters larger than 20 km in diameter. We show that 49 craters (out of the 521) correspond to the complete crater population of this size formed over the last 600 Ma. Our results on Mars show that the flux of both small (> 5 m) and large asteroids (> 1 km) are coupled, does not vary between each other over the last 600 Ma. Existing data sets for large craters on the Earth and the Moon are analyzed and compared to our results on Mars. On Earth, we infer the formation location of a set of impact craters thanks to plate tectonic reconstruction and show that a cluster of craters formed during the Ordovician period, about 470 Ma ago, appears to be a preservation bias. On the Moon, the late increase seen in the crater age signal can be due to the uncertain calibration method used to date those impacts (i.e. rock abundance in lunar impact ejecta), and other calibrations are consistent with a constant crater production rate. We conclude to a coupling of the crater production rate between kilometer-size craters (∼100 m asteroids) and down to ∼100 m in diameter (∼5 m asteroids) in the inner Solar System. This is consistent with the traditional model for delivering asteroids to planet-crossing obits: the Yarkovsky effect slowly pushes the large debris from asteroid break-ups towards orbital resonances while smaller debris are grinded through collisional cascades. This suggests that the long-term impact flux of asteroids > 5 m is most likely constant over the last 600 Ma, and that the influence of past asteroid break-ups in the cratering rate for D > 100 m is limited or inexistent.
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format Journal Article
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institution Curtin University Malaysia
institution_category Local University
language English
last_indexed 2025-11-14T11:35:08Z
publishDate 2022
publisher ELSEVIER
recordtype eprints
repository_type Digital Repository
spelling curtin-20.500.11937-907982023-04-24T04:12:09Z Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon? Lagain, Anthony Kreslavsky, M. Baratoux, D. Liu, Yebo Devillepoix, Hadrien Bland, Philip Benedix, Gretchen Doucet, Luc Servis, K. Science & Technology Physical Sciences Geochemistry & Geophysics impact flux craters automatic crater detection inner Solar System CRATER AGES BOMBARDMENT CHRONOLOGY HISTORY The impact flux over the last 3 Ga in the inner Solar System is commonly assumed to be constant through time due to insufficient data to warrant a different choice for this range of time. However, asteroid break-up events in the main belt may have been responsible for cratering spikes over the last ∼2 Ga on the Earth-Moon system. Due to its proximity with the main asteroid belt, i.e., the main impactors reservoir, Mars is at the outpost of these events with respect to the other inner planets. We investigate here, from automatic crater identification, the possible variations of the size frequency distributions of impactors from the record of small craters of 521 impact craters larger than 20 km in diameter. We show that 49 craters (out of the 521) correspond to the complete crater population of this size formed over the last 600 Ma. Our results on Mars show that the flux of both small (> 5 m) and large asteroids (> 1 km) are coupled, does not vary between each other over the last 600 Ma. Existing data sets for large craters on the Earth and the Moon are analyzed and compared to our results on Mars. On Earth, we infer the formation location of a set of impact craters thanks to plate tectonic reconstruction and show that a cluster of craters formed during the Ordovician period, about 470 Ma ago, appears to be a preservation bias. On the Moon, the late increase seen in the crater age signal can be due to the uncertain calibration method used to date those impacts (i.e. rock abundance in lunar impact ejecta), and other calibrations are consistent with a constant crater production rate. We conclude to a coupling of the crater production rate between kilometer-size craters (∼100 m asteroids) and down to ∼100 m in diameter (∼5 m asteroids) in the inner Solar System. This is consistent with the traditional model for delivering asteroids to planet-crossing obits: the Yarkovsky effect slowly pushes the large debris from asteroid break-ups towards orbital resonances while smaller debris are grinded through collisional cascades. This suggests that the long-term impact flux of asteroids > 5 m is most likely constant over the last 600 Ma, and that the influence of past asteroid break-ups in the cratering rate for D > 100 m is limited or inexistent. 2022 Journal Article http://hdl.handle.net/20.500.11937/90798 10.1016/j.epsl.2021.117362 English http://purl.org/au-research/grants/arc/DP170102972 http://purl.org/au-research/grants/arc/FT170100024 http://creativecommons.org/licenses/by-nc-nd/4.0/ ELSEVIER fulltext
spellingShingle Science & Technology
Physical Sciences
Geochemistry & Geophysics
impact flux
craters
automatic crater detection
inner Solar System
CRATER
AGES
BOMBARDMENT
CHRONOLOGY
HISTORY
Lagain, Anthony
Kreslavsky, M.
Baratoux, D.
Liu, Yebo
Devillepoix, Hadrien
Bland, Philip
Benedix, Gretchen
Doucet, Luc
Servis, K.
Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?
title Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?
title_full Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?
title_fullStr Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?
title_full_unstemmed Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?
title_short Has the impact flux of small and large asteroids varied through time on Mars, the Earth and the Moon?
title_sort has the impact flux of small and large asteroids varied through time on mars, the earth and the moon?
topic Science & Technology
Physical Sciences
Geochemistry & Geophysics
impact flux
craters
automatic crater detection
inner Solar System
CRATER
AGES
BOMBARDMENT
CHRONOLOGY
HISTORY
url http://purl.org/au-research/grants/arc/DP170102972
http://purl.org/au-research/grants/arc/DP170102972
http://hdl.handle.net/20.500.11937/90798

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