Magnetic Field Signatures of Craters on Mars

Mittelholz, A.; Steele, S. C.; Fu, R. R.; Johnson, C. L.; Lillis, R. J.; Stucky de Quay, G.

doi:10.1029/2023gl106788

Geophysical Research Letters

2024

DOI: 10.1029/2023gl106788

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Magnetic Field Signatures of Craters on Mars

A. Mittelholz,

S. C. Steele,

R. R. Fu

et al.

Abstract: Craters on Mars are a window into Mars' past and the time they were emplaced. Because the crust is heated and shocked during impact, craters can demagnetize or magnetize the crust depending on the presence or absence of a dynamo field at the time of impact. This concept has been used to constrain dynamo timing. Here, we investigate magnetic anomalies associated with craters larger than 150 km. We find that most of those craters, independent of age, exhibit demagnetization signatures in the form of a central ma… Show more

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2024

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Cited by 2 publications

References 48 publications

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Evidence for Magnetized Basin Ejecta on the Moon From Observations and Modeling of Demagnetized Craters

Park,

Garrick‐Bethell,

Johnson

et al. 2024

JGR Planets

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The formation of lunar crustal magnetic anomalies is not well understood, and most anomalies are not associated with any obvious geologic features. To investigate further, we studied lunar craters from 100 to 400 km in diameter (totaling 305 craters) that may have demagnetized the crust. We find that the four craters Chaplygin, Keeler, Gauss, and Fermi are highly likely to have demagnetized the crust, based on our statistical methods. We modeled the magnetic source of these craters as a simple hole in a thin magnetized plate, representing the destruction of a surficial magnetized layer (Hypothesis 1). Alternatively, we also simulated the impact demagnetization of deeper‐seated magnetism in the crust by shock and temperature (Hypothesis 2). Some interior magnetization remains unexplained under both hypotheses, but the destruction of a pre‐existing surficial layer of magnetized material is consistent with the location of the peak in each crater's magnetic field. We also find three of the craters are inversely correlated with remotely sensed iron, further supporting our interpretation that the craters demagnetized a surficial layer. The four craters are located on magnetized ejecta deposits from the South Pole‐Aitken, Orientale, and Crisium basins. Hence, these four craters further support the hypothesis that large provinces of magnetized material on the Moon arise from hot impact ejecta that cooled in a dynamo field.

show abstract

Evidence for Magnetized Basin Ejecta on the Moon From Observations and Modeling of Demagnetized Craters

Park,

Garrick‐Bethell,

Johnson

et al. 2024

JGR Planets

View full text Add to dashboard Cite

show abstract

Weak magnetism of Martian impact basins may reflect cooling in a reversing dynamo

Steele,

Fu,

Mittelholz

et al. 2024

Nat Commun

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Magnetic Field Signatures of Craters on Mars

Cited by 2 publications

References 48 publications

Evidence for Magnetized Basin Ejecta on the Moon From Observations and Modeling of Demagnetized Craters

Evidence for Magnetized Basin Ejecta on the Moon From Observations and Modeling of Demagnetized Craters

Weak magnetism of Martian impact basins may reflect cooling in a reversing dynamo

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