Evidence of extensive lunar crust formation in impact melt sheets 4,330 Myr ago

White, L. F.; Černok, Ana; Darling, James; Whitehouse, Martin J.; Joy, K. H.; Cayron, Cyril; Dunlop, Joseph; Tait, K. T.; Anand, M.

doi:10.1038/s41550-020-1092-5

Cited by 30 publications

(26 citation statements)

References 38 publications

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“…There is another well-known cubic-monoclinic phase transformation in which this special feature is visible; it is that in zirconia. Even if the OR is not the same (the correspondence is just the identity in zirconia), we observed in previous studies the "dice-5" feature in monoclinic zirconia that comes from industrial refractory walls of glass furnaces [68], from Earth crustal rocks extracted under a meteoric impact [69], and from the Moon [70]. It was clear to us that this "dice-5" feature marks the coexistence of two ORs, but we could not explain it at that time, even by considering the tetragonal phase of zirconia as an intermediate state.…”

Section: Future Workmentioning

confidence: 62%

What EBSD and TKD Tell Us about the Crystallography of the Martensitic B2-B19′ Transformation in NiTi Shape Memory Alloys

Cayron

2020

Crystals

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The complex and intricate microstructure of B19′ martensite in shape memory nickel titanium alloys is generally explained with the Phenomenological Theory of Martensitic Crystallography (PTMC). Over the last decade, we have developed an alternative approach that supposes the existence of a “natural” parent–daughter orientation relationship (OR). As the previous TEM studies could not capture the global crystallographic characteristics of the B2→B19′ transformation required to discriminate the models, we used Electron BackScatter Diffraction (EBSD) and Transmission Kikuchi Diffraction (TKD) to investigate a polycrystalline NiTi alloy composed of B19′ martensite. The EBSD maps show the large martensite plates and reveal the coexistence of different ORs. The TKD maps permit us to image the “twins” and confirm the continuum of orientations suspected from EBSD. The results are interpreted with the alternative approach. The predominant OR in EBSD is the “natural” OR for which the dense directions and dense planes of B2 and B19′ phases are parallel—i.e., (010)B19′//(110)B2 and [101]B19′//[ 1 ¯ 11]B2. The natural OR was used to automatically reconstruct the prior parent B2 grains in the EBSD and TKD maps. From the distortion matrix associated with this OR, we calculated that the habit plane could be (1 1 ¯ 2)B2//(10 1 ¯ )B19′. The traces of these planes are in good agreement with the EBSD maps. We interpret the other ORs as “closing-gap” ORs derived from the natural OR to allow the compatibility between the distortion variants. Each of them restores a parent symmetry element between the variants that was lost by distortion but preserved by correspondence.

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Section: Future Workmentioning

confidence: 62%

What EBSD and TKD Tell Us about the Crystallography of the Martensitic B2-B19′ Transformation in NiTi Shape Memory Alloys

Cayron

2020

Crystals

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“…Context is, therefore, critical to interpreting whether this high-temperature phase formed in response to a lightning strike, impact event, or other extreme pressure–temperature excursion. For example, petrographic context enabled White et al 39 to interpret evidence for precursor cubic ZrO 2 in a lunar sample as indicative of crystallization from a superheated impact melt 39 . Conversely, documenting precursor cubic ZrO 2 in glasses of unknown origin would be insufficient to infer an impact origin for such samples.…”

Section: Discussionmentioning

confidence: 99%

The response of zircon to the extreme pressures and temperatures of a lightning strike

Kenny

Pasek

2021

Sci Rep

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Hypervelocity impacts can produce features in zircon that are not normally produced by endogenic processes. However, lightning can also induce extreme pressure–temperature excursions, and its effect on zircon has not been studied. With the aim to recognise features that form in response to extreme pressure–temperature excursions but are not unique to hypervelocity impacts, we imaged and undertook microstructural characterization of zircon in a fulgurite (a tubular body of glass and fused clasts that formed in response to a lightning strike). We document zircon with granular ZrO2 and rims of vermicular ZrO2, features which vary in abundance with increasing distance from the fulgurite’s central void. This indicates that these features formed in response to the lightning strike. Zircon dissociation to ZrO2 and SiO2 is a high-temperature, relatively low-pressure phenomenon, consistent with previous suggestions that lightning strikes involve extreme temperatures as well as pressures greater than those usually generated in Earth’s crust but rarely > 10 GPa. The rims of monoclinic ZrO2 record crystallographic evidence for precursor cubic ZrO2, demonstrating that cubic ZrO2 is not unique to hypervelocity impacts. Given the likelihood that this fulgurite experienced pressures of, at most, a few GPa, evidence for cubic ZrO2 indicates peak temperatures > 2000 °C.

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“…However, they also refer to three ferroan anorthosites dated by other authors at 4.43 AE 0.03, 4.47 AE 0.07, and 4.53 AE 0.12 Ga, which could record earlier impact and recrystallization events. Numbers of impact melt clasts, dated at~4.35 Ga, offer vestiges of one or more large impact structures during that period (Nemchin et al 2008;Grange et al 2013;and White et al 2020; see also Hartmann [2019] for review). Figures 1, 2a, and 3, of our present paper imply very intense bombardment, including multiple impacts of basin-forming magnitude, along with extreme crater oversaturation, during the suggested periods of magma ocean presence.…”

Section: Intense Early Bombardment: Consequences For Megaregolith Evomentioning

confidence: 99%

“…2013; and White et al. 2020; see also Hartmann [2019] for review). Figures 1, 2a, and 3, of our present paper imply very intense bombardment, including multiple impacts of basin‐forming magnitude, along with extreme crater oversaturation, during the suggested periods of magma ocean presence.…”

Section: Intense Early Bombardment: Consequences For Megaregolith Evomentioning

confidence: 99%

Effects of early intense bombardment on megaregolith evolution and on lunar (and planetary) surface samples

Hartmann

Morbidelli

2020

Meteorit & Planetary Scien

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Impact rates in the first 500 Myr of the solar system are critical to an understanding of lunar geological history, but they have been controversial. The widely accepted, post‐Apollo paradigm of early lunar impact cratering (about 1975–2014) proposed very low or negligible impact cratering in the period from accretion (>4.4 Ga) to ~4.0 Ga ago, followed by an ~170 million year long spike of cataclysmic cratering, during which most prominent multi‐ring impact basins formed at age ~3.9 Ga. More recent dynamical models suggest very early intense impact rates, declining throughout the period from accretion until an age of ~3.0 Ga. These models remove the basin‐forming spike. This shift has important consequences vis‐à‐vis megaregolith evolution and properties of rock samples that can be collected on the lunar surface today. We adopt the Morbidelli et al. (2018) “accretion tail” model of early intense bombardment, declining as a function of time. We find effects differing from the previous models: early crater saturation and supersaturation; disturbance of magma ocean solidification; deep early megaregolith; and erosive destruction of the earliest multi‐ring basins, their impact melts, and their ejecta blankets. Our results explain observations such as differences in numbers of early lunar impact melts versus numbers of early igneous crustal rocks, highland breccias containing impact melts as old as 4.35 Ga, absence of a 170 Myr long spike in impact melt ages at 3.9 Ga among lunar and asteroidal meteorites, and GRAIL observations of lunar crustal structure.

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Evidence of extensive lunar crust formation in impact melt sheets 4,330 Myr ago

Cited by 30 publications

References 38 publications

What EBSD and TKD Tell Us about the Crystallography of the Martensitic B2-B19′ Transformation in NiTi Shape Memory Alloys

What EBSD and TKD Tell Us about the Crystallography of the Martensitic B2-B19′ Transformation in NiTi Shape Memory Alloys

The response of zircon to the extreme pressures and temperatures of a lightning strike

Effects of early intense bombardment on megaregolith evolution and on lunar (and planetary) surface samples

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