Lunar compositional asymmetry explained by mantle overturn following the South Pole–Aitken impact

The spatial distribution of mare basalts, titanium and KREEP (potassium, rare earth elements and phosphorus) on the Moon is asymmetrical between the nearside and farside. These asymmetries cannot be readily explained by solidification of a global magma ocean and subsequent mantle overturn, which sho...

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Bibliographic Details
Published in:Nature geoscience 2022-01, Vol.15 (1), p.37-41
Main Authors: Zhang, Nan, Ding, Min, Zhu, Meng-Hua, Li, Huacheng, Li, Haoyuan, Yue, Zongyu
Format: Article
Language:English
Subjects:
704/445/209
704/445/210
704/445/845
Asymmetry
Basalt
Convection
Earth and Environmental Science
Earth mantle
Earth Sciences
Earth System Sciences
Geochemistry
Geology
Geophysics/Geodesy
Gravitational instability
Gravity
Hemispheric laterality
Ilmenite
Kreep
Lava
Lunar surface
Magma
Mantle convection
Mathematical models
Moon
Numerical simulations
Oceans
Overturn
Phosphorus
Potassium
Rare earth elements
Solidification
South Pole
Spatial distribution
Titanium
Trace elements
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Summary:The spatial distribution of mare basalts, titanium and KREEP (potassium, rare earth elements and phosphorus) on the Moon is asymmetrical between the nearside and farside. These asymmetries cannot be readily explained by solidification of a global magma ocean and subsequent mantle overturn, which should result in a layered and spherically symmetric lunar interior. Alternative scenarios have been proposed to explain the observed compositional asymmetry, but its origin remains enigmatic. Here, we present hydro- and mantle convection numerical simulations of the giant impact event that formed the South Pole–Aitken basin—the largest impact basin on the Moon—and the subsequent impact-induced convection with the assistance of gravitational instability. We find that the impact induces thermochemical instabilities that drive the dense KREEP-rich ilmenite-bearing cumulate to migrate towards the nearside following lunar magma ocean solidification. This results in the formation of a chemical reservoir under the nearside crust that could explain the observed geochemical asymmetries. We suggest that enrichments of ilmenite and KREEP in the nearside hemisphere following the South Pole–Aitken impact event provide a viable explanation for the wide composition range of mare basalts observed on the lunar surface. The compositional asymmetry between the Moon’s near- and farsides can be explained as the result of impact-induced mantle convection and gravitational instability, according to numerical modelling of the South Pole–Aitken impact and the ensuing mantle evolution.
ISSN:1752-0894
1752-0908
DOI:10.1038/s41561-021-00872-4