Nano- and micro-structures in lunar zircon from Apollo 15 and 16 impactites: implications for age interpretations

Kusiak, Monika A.; Kovaleva, Elizaveta; Vanderliek, Dennis; Becker, Harry; Wilke, Franziska; Schreiber, Anja; Wirth, Richard

doi:10.1007/s00410-022-01977-8

Cited by 5 publications

(1 citation statement)

References 69 publications

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“…Linear regions of >45 GPa band ratios may reflect spatial localization of shock-induced impact melting along nano-scale fractures or veins [36]. Semiparallel planar fractures and veins have been observed in a variety of shocked silicate and phosphate minerals [37,38,39,40], and the spatially localized damage zones observed in both flakes is consistent with an interpretation of sample 15445 as an impact melt shocked breccia.…”

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confidence: 81%

Nanoscale Characterization of Space Weathered Lunar Samples

Orlando,

Grice,

Stancil

et al. 2024

Preprint

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High-resolution nanoscale Fourier transform infrared (Nano-FTIR) imaging and spectroscopy correlated with photoluminescence measurements of a lunar ilmenite basalt (12016) and recrystallized impact melt breccia (15445), Apollo samples with different origins and history, reveal distinct chemical differences associated with the parent-rock geochemistry and space weathering effects. Intrinsic or delivered Nd3+ and an amorphous silicate glass component produced by solar wind bombardment are observed on exterior surfaces, whereas intrinsic Cr3+ and/or trapped electron states likely produced by energetic x-rays or cosmic rays are observed in interior surfaces. Spatially localized 1050 cm-1/935 cm-1 band ratios in Nano-FTIR hyperspectral maps may reflect shock-induced nanostructures in the impact melt brecci, while shifts in silicate band positions may indicate general space-weathering. Collectively, the shock features, amorphous silicate over-layer, electron-trap states and differential Nd3+ and Cr3+ ratios provide compelling evidence and proxies for space weathering and transformation events not easily obtained with conventional far-field optical analysis techniques.

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supporting

confidence: 81%

Nanoscale Characterization of Space Weathered Lunar Samples

Orlando,

Grice,

Stancil

et al. 2024

Preprint

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Microstructural and isotopic analysis of shocked monazite from the Hiawatha impact structure: development of porosity and its utility in dating impact craters

Hyde,

Kenny,

Whitehouse

et al. 2024

Contrib Mineral Petrol

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U–Pb geochronology of shocked monazite can be used to date hypervelocity impact events. Impact-induced recrystallisation and formation of mechanical twins in monazite have been shown to result in radiogenic Pb loss and thus constrain impact ages. However, little is known about the effect of porosity on the U–Pb system in shocked monazite. Here we investigate monazite in two impact melt rocks from the Hiawatha impact structure, Greenland by means of nano- and micrometre-scale techniques. Microstructural characterisation by scanning electron and transmission electron microscopy imaging and electron backscatter diffraction reveals shock recrystallisation, microtwins and the development of widespread micrometre- to nanometre-scale porosity. For the first time in shocked monazite, nanophases identified as cubic Pb, Pb3O4, and cerussite (PbCO3) were observed. We also find evidence for interaction with impact melt and fluids, with the formation of micrometre-scale melt-bearing channels, and the precipitation of the Pb-rich nanophases by dissolution–precipitation reactions involving pre-existing Pb-rich high-density clusters. To shed light on the response of monazite to shock metamorphism, high-spatial-resolution U–Pb dating by secondary ion mass spectrometry was completed. Recrystallised grains show the most advanced Pb loss, and together with porous grains yield concordia intercept ages within uncertainty of the previously established zircon U–Pb impact age attributed to the Hiawatha impact structure. Although porous grains alone yielded a less precise age, they are demonstrably useful in constraining impact ages. Observed relatively old apparent ages can be explained by significant retention of radiogenic lead in the form of widespread Pb nanophases. Lastly, we demonstrate that porous monazite is a valuable microtexture to search for when attempting to date poorly constrained impact structures, especially when shocked zircon or recrystallised monazite grains are not present.

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