Impact Melt Facies in the Moon's Crisium Basin: Identifying, Characterizing, and Future Radiogenic Dating

Runyon, K. D.; Moriarty, D. P.; Denevi, Brett W.; Greenhagen, B. T.; Morgan, G. A.; Young, K. E.; Cohen, B. A.; Bogert, C. H. van der; Hiesinger, H.; Jozwiak, L. M.

doi:10.1029/2019je006024

Cited by 13 publications

(14 citation statements)

References 74 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Specifically, mantle materials ejected and melted during the South Pole‐Aitken basin‐forming event appear to be dominated by pyroxene + ilmenite‐ and KREEP‐bearing cumulates (Moriarty & Pieters, 2018; Moriarty et al., 2013; Moriarty, Dygert, et al., 2021; Moriarty, Watkins, et al., 2021; Nakamura et al., 2009). The impact melt associated with the Crisium basin is dominated by low‐Ca pyroxene (Runyon et al., 2020). Generation of an olivine‐poor, pyroxene‐rich upper mantle has been modeled by Prissel and Gross (2020).…”

Section: Discussionmentioning

confidence: 99%

Multiple Shallow Crustal Origins for Spinel‐Bearing Lithologies on the Moon: A Perspective From the Luna 20 Mission

et al. 2022

Self Cite

View full text Add to dashboard Cite

Spinel (predominantly the MgAl 2 O 4 -end member)-bearing crustal lithologies have long been recognized in the Apollo sample collection. However, such lithologies are rather rare and individual samples are small in mass (<1 g). It has been inferred since the early 1970s that these lithologies (e.g., extensively shocked spinel ± cordierite troctolite clasts) were excavated during basin-forming events from the deep lunar crust and/or upper mantle

show abstract

Section: Discussionmentioning

confidence: 99%

Multiple Shallow Crustal Origins for Spinel‐Bearing Lithologies on the Moon: A Perspective From the Luna 20 Mission

et al. 2022

Self Cite

View full text Add to dashboard Cite

show abstract

“…Instead, the largest basins on the Moon tend to exhibit low‐Ca pyroxene‐dominated lithologies in their impact melt and ejecta (Crites & Lucey, 2015; Hurwitz & Kring, 2014; Lemelin et al., 2019; Melosh et al., 2017; Moriarty et al., 2013; Moriarty & Pieters, 2018; Nakamura et al., 2009; Ohtake et al., 2014; Runyon et al., 2020). This, along with geophysical observations, has been invoked to argue that the upper mantle is dominated by pyroxenes (Hurwitz & Kring, 2014; Kuskov et al., 2015; Melosh et al., 2017).…”

Section: Introductionmentioning

confidence: 99%

Evidence for a Stratified Upper Mantle Preserved Within the South Pole‐Aitken Basin

et al. 2021

Self Cite

View full text Add to dashboard Cite

The evolution and compositional structure of the lunar mantle has been extensively modeled but insufficiently constrained by observations. Here, we identify and characterize mantle materials exposed by the Moon's largest impact basin to better understand the composition, stratigraphy, and evolution of the upper mantle. The vast South Pole-Aitken Basin (SPA) exhibits a broad, crescent-shaped thorium and potassium distribution. These incompatible elements are predicted to be concentrated in the dregs of the lunar magma ocean during end-stage crystallization. Through consideration of basin formation models convolved with subsequent geologic evolution, we demonstrate that the distribution and implied stratigraphy of Th-and K-bearing materials across SPA are consistent with an upper mantle ejecta origin. The most pristine exposures of these materials are confined to northwest SPA and also exhibit elevated Ti and Fe (relative to the farside highlands) in association with a gabbronoritic mineralogy. This is consistent with latestage magma ocean assemblages predicted by petrologic models. In contrast, SPA impact melt derived from greater depths is associated with a low-Ca pyroxene-dominated assemblage. Together, these compositional patterns are evidence for a stratified ancient upper mantle. Importantly, the incompatible-element-enriched, ilmenite-bearing ferroan gabbronoritic cumulates evidently had not participated in gravitational overturn at the time of SPA formation. Contrary to recent hypotheses invoking nearside sequestration of incompatible elements to explain hemispherical differences in crustal building and volcanic resurfacing, it follows that incompatible elements were globally distributed in the magma ocean at the time of SPA formation. Plain Language Summary Like the Earth, the Moon is layered into a crust and mantle. The Moon's layering was shaped by an early global melting event known as the "Lunar Magma Ocean." As the magma ocean solidified, dense minerals sank to form the mantle, while less-dense minerals floated to form the crust. Elements such as thorium are not easily incorporated into mineral structures, and remain in the liquid. Because of this, a thorium-rich dreg layer was sandwiched between the crust and mantle. These dregs are very dense and are expected to sink into the underlying mantle during or soon after crystallization. We demonstrate that the Moon's largest and oldest impact basin excavated material from this dense, thorium-rich layer before it sank. The exposed material was then diluted and obscured by four billion years of impact cratering and volcanic eruptions. However, we identify several pristine exposures created by recent craters. The impact basin also melted rocks from greater depths than the rocks it ejected. These melted rocks exhibit a much different composition. This indicates that the lunar upper mantle included two compositionally distinct layers that were exposed in different ways by this large impact event. These results have important implications for understanding the ...

show abstract

“…Spudis and Sliz (2016) [13] identified and dated the impact melt sheets in the rim of the Crisium basin, suggesting that the western Crisium kipukas contain mare-like, Ca, Fe-rich pyroxene compositions. Runyon et al (2020) [14] further characterized possible impact melt sheets, indicating that Yerkes crater likely contains the Crisium melt materials. Thus, a detailed geologic map of the Crisium basin from the newly acquired remote sensing observations is necessary to understand the geologic context, regional crustal composition, flooding history of mare basalts, and geochronology.…”

Section: Introductionmentioning

confidence: 99%

Geomorphology, Mineralogy, and Geochronology of Mare Basalts and Non-Mare Materials around the Lunar Crisium Basin

Cao

Ling

et al. 2021

Remote Sensing

View full text Add to dashboard Cite

The Nectarian-aged Crisium basin exhibits an extremely thin crust and complicated lunar geological history. This large multi-ring impact basin is characterized by prolonged lunar volcanism ranging from the Imbrian age to the Eratosthenian period, forming the high-Ti mare unit, low-Ti mare basalts, and very low-Ti mare unit. We produced an updated geological map of the Crisium basin and defined four mare units (Im1: 3.74 Ga; Im2: 3.49 Ga; Im3: 3.56 Ga; EIm: 2.49 Ga) in terms of distinct composition and mineralogy. Olivine was widely determined in the Ti-rich Im1, implying the hybridization source in the lunar mantle with the occurrence of small-scale convective overturn. The major phase of low-Ti basaltic volcanism occurred c.a. 3.5 Ga, forming Im2 and Im3 in the western area. The youngest mare unit (EIm) has slight variations of pyroxene compositions, implying a decrease of calcic content of basaltic volcanisms with time. Later, distal material transports from large impact events in highlands could complicate the mixing of local mare basalts in the Copernicus age, especially the Im3 unit. The identified olivine-bearing outcrops and widely Mg-rich materials (Mg# > 70, where Mg# = molar 100 × Mg/(Mg + Fe)) in the western highlands, assumed to be the occurrence of the Mg-suite candidates, require future lunar exploration missions to validate.

show abstract

Impact Melt Facies in the Moon's Crisium Basin: Identifying, Characterizing, and Future Radiogenic Dating

Cited by 13 publications

References 74 publications

Multiple Shallow Crustal Origins for Spinel‐Bearing Lithologies on the Moon: A Perspective From the Luna 20 Mission

Multiple Shallow Crustal Origins for Spinel‐Bearing Lithologies on the Moon: A Perspective From the Luna 20 Mission

Evidence for a Stratified Upper Mantle Preserved Within the South Pole‐Aitken Basin

Geomorphology, Mineralogy, and Geochronology of Mare Basalts and Non-Mare Materials around the Lunar Crisium Basin

Contact Info

Product

Resources

About