Long-lived volcanism expressed through mare infilling, domes and IMPs in the Arago region of the Moon

N. Schnuriger*, J. Flahaut, M. Martinot, S. D. Chevrel

*Corresponding author for this work

Research output: Contribution to JournalArticleAcademicpeer-review

Abstract

Mare Tranquillitatis corresponds to the deposit of successive Early to Late Imbrian basaltic units filling the Tranquillitatis basin on the Moon. The present study focuses on the western half of the mare, in the vicinity of the Arago crater (6.16°N, 21.42°E). High resolution datasets from recent remote sensing missions were used to reconstruct the geologic history of the area, which includes a variety of geological features such as: 8 extrusive domes, numerous wrinkle ridges, a sinuous rille and 37 Irregular Mare Patches (IMPs). We performed crater counting to date the domes emplacement and estimated the domes lava rheologic properties (plastic viscosities, lava effusion rates, and durations of effusion) using their geometric characteristics. As a result we classify the Arago domes into three groups: E1-type domes (Arago 1 and 8), H1-type domes (Arago 4 to 7), and B-type domes (Arago 2 and 3) respectively emplaced ​~ ​3.7 ​Ga, ~3.4 ​Ga, and ~2.8 ​Ga ago. IMPs are observed in the younger mare unit and on the top of the Arago 6 dome; they likely correspond to a late stage of waning mare volcanism in the area. Both IMPs and domes have a composition similar to the surrounding mare in the VNIR spectral domain, consistent with mafic materials. The exceptionally long-lived volcanism and its diversity recorded in the Arago region may be related to both a Th-rich anomaly reported nearby and to the large-scale magma center responsible for the Lamont positive Bouguer anomaly. In addition, volcanic features of the Arago region are superimposed on a Ti-rich mare unit visited by the Apollo 11 crew 175 ​km to the south at Tranquility Base. The geological and historical richness of this region makes it a compelling site for future science and/or In Situ Resources Utilization (ISRU) driven missions to the Moon.

Original languageEnglish
Article number104901
Pages (from-to)1-13
Number of pages13
JournalPlanetary and Space Science
Volume185
Early online date17 Mar 2020
DOIs
Publication statusPublished - Jun 2020

Funding

The authors wishes to thank F. Zhang and an anonymous reviewer for their help in significantly improving our manuscript. The authors are also grateful to Sylvain Breton and Qian Huang for fruitful discussions. N. Schnuriger started this research project as a bachelor’s intern at IRAP Toulouse and is now employed as a PhD student at CRPG Nancy at the time of writing. Both N. Schnuriger and J. Flahaut’s contributions were and are supported by the CNES “Appels à Projets de Recherche” ExoMars and Luna attributed to J. Flahaut. J. Flahaut acknowledges funding from the CNRS Momentum, CNES APR and LUE , France future leader programs. This is CRPG contribution N°2719.

FundersFunder number
CNRS Momentum
Centre National d’Etudes Spatiales

    Keywords

    • Apollo 11
    • Domes
    • IMPs
    • Mare basalts
    • Moon
    • Volcanism

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