Your search keyword '"Nemchin, A. A."' showing total 470 results

1. Post-Imbrium Pb–Pb isochron ages for Apollo basaltic impact melt samples 14078 and 68415

Author

Joshua F. Snape, Alexander A. Nemchin, Martin J. Whitehouse, Qiu-Li Li, Yu Liu, Nicholas E. Timms, Timmons Erickson, and Gretchen K. Benedix

Subjects

Pb, Apollo, geochronology, isotope, impact, Science

Abstract

The Apollo 14 and 16 missions returned several samples commonly interpreted as crystalline impact melt, with ages of approximately 3800–3850 Ma. Previous work has suggested that these rocks formed in one or more pre-Imbrium basin forming impact(s). By contrast, recent ages determined for a range of lunar breccias provide compelling evidence that the Imbrium basin was formed at approximately 3920 Ma. Using an approach previously demonstrated in lunar basalts, Pb–Pb isochron ages are determined for two of these proposed impact melt samples (14078: 3848 ± 4 Ma; and 68415: 3834 ± 11 Ma). In the case of 14078, the least radiogenic Pb isotopic compositions measured here are interpreted as representing the initial Pb isotopic composition of the sample. This value indicates derivation from a source (or sources) with high 238U/204Pb ratios (approx. 2400), similar to those predicted for the Apollo 14 high-Al and very high-K basalts. It was not possible to determine an equivalent initial Pb isotopic composition for 68415, but Pb isotope evolution models indicate that the sample would have been derived from lithologies with lower 238U/204Pb source ratios (approx. 1000). In both cases, the samples are interpreted as having been formed by impacts local to the Apollo 14 and Apollo 16 landing sites.

Published

2024

2. Petrology and chronology of mare components in lunar basaltic breccia meteorite Northwest Africa 12384.

Author

Yen, Christopher J.‐K., Carpenter, Paul K., Deligny, Cécile, Nemchin, Alexander, Merle, Renaud, Irving, Anthony J., Nishiizumi, Kunihiko, Caffee, Marc W., Jull, A. J. Timothy, Whitehouse, Martin, and Jolliff, Bradley L.

Subjects

OBSIDIAN, BRECCIA, PETROLOGY, COSMIC rays, MINERALOGY, METEORITES

Abstract

Northwest Africa (NWA) 12384 is a lunar polymict breccia composed almost entirely of basaltic components. The clast content includes low‐ to very‐low‐Ti volcanic picritic glass, basaltic vitrophyre, and crystalline pigeonite basalt—an assemblage of volcanic materials that can be tested for petrogenetic relationships. We present the inferred history of select mare components of NWA 12384 as suggested by texture, mineralogy, and petrography, and compare them to Apollo samples and other lunar meteorites. In addition, we used the volcanic glasses in the breccia as a primary composition for crystallization modeling and comparison to the lithic clast compositions. We find that the mafic clasts in NWA 12384 cannot be derived from the picritic glass through a common liquid line of descent because of higher Ti content, though they may have crystallized from a separate, common liquid line of descent. These clasts could represent local source‐region heterogeneity or differential assimilation of more Ti‐rich material. Pb‐Pb SIMS analyses of a large basalt clast in NWA 12384 reveal an age of 3044 ± 41 Ma (2σ), which is used together with the chemical data and 4π cosmic ray exposure age of less than 20 kyr and terrestrial age of between 3.1 and 17.3 kyr to constrain the possible locations of provenance for this meteorite. [ABSTRACT FROM AUTHOR]

Published

2024

3. Post-Imbrium Pb–Pb isochron ages for Apollo basaltic impact melt samples 14078 and 68415

Author

Snape, Joshua F., primary, Nemchin, Alexander A., additional, Whitehouse, Martin J., additional, Li, Qiu-Li, additional, Liu, Yu, additional, Timms, Nicholas E., additional, Erickson, Timmons, additional, and Benedix, Gretchen K., additional

Published

2024

4. The internal structure and geodynamics of Mars inferred from a 4.2-Gyr zircon record

Author

Costa, Maria M., Jensen, Ninna K., Bouvier, Laura C., Connelly, James N., Mikouchi, Takashi, Horstwood, Matthew S. A., Suuronen, Jussi-Petteri, Moynier, Frédéric, Deng, Zhengbin, Agranier, Arnaud, Martin, Laure A. J., Johnson, Tim E., Nemchin, Alexander A., and Bizzarro, Martin

Published

2020

5. Large impact cratering during lunar magma ocean solidification

Author

K. Miljković, M. A. Wieczorek, M. Laneuville, A. Nemchin, P. A. Bland, and M. T. Zuber

Subjects

Science

Abstract

Lunar impact basins formed during the magma ocean solidification should have formed almost unidentifiable topographic and crustal thickness signatures, thus may escape detection. This result allows for a higher impact flux in the earliest epoch of Earth-Moon evolution.

Published

2021

6. Pb Isotope Signature of a Low-Ό (238U/204Pb) Lunar Mantle Component

Author

Merle, Renaud E., Nemchin, Alexander A., Whitehouse, Martin J., Kenny, Gavin G., Snape, Joshua F., Merle, Renaud E., Nemchin, Alexander A., Whitehouse, Martin J., Kenny, Gavin G., and Snape, Joshua F.

Abstract

The chemical and isotopic characteristics of terrestrial basalts are constrained within the concept of mantle chemical geodynamics that explains the existing variety of basaltic rocks within a framework of several end-member reservoirs in Earth's mantle. In contrast, there is no comparable fully developed model explaining the isotopic composition of lunar basaltic rocks, in part owing to the lack of well-constrained age-isotope relationships in different groups of basalts identified on the Moon. Notably, the absence of agreement upon ages includes basalts from a unique group of meteorites collectively known as 'YAMM' (basalts Yamato-793169: Y-793169, Asuka-881757: A-881757, Miller Range 05035: MIL 05035 and regolith breccia Meteorite Hill 01210: MET 01210), which appear to show chemical signatures different from all other known lunar basaltic rocks. We present high-precision Pb-Pb ages and initial Pb isotopic ratios for two samples from this group, MIL 05035 and A-881757. These meteorites have Pb isotope ratios different from those of the other lunar basalts, suggesting they are derived from a distinct and depleted mantle source, with a U-238/Pb-204 ratio (mu value) lower than any other mantle source. Their depletion in rare earth elements, in conjunction with recalculated initial Nd and Sr isotopic ratios from published data and using our new age, appear to support this conclusion. The chemical and Sr-Nd-Pb isotopic characteristics of this low-mu source appear to be the opposite of those of the KREEP reservoir and many, if not all, features described in other lunar basalts (such as low- and high-Ti mare basalts) can be explained by a binary mixing of material derived from low-mu and KREEP-like reservoirs. This mixing might be the result of a slow, convection-like mantle overturn.

Published

2024

7. Large impact cratering during lunar magma ocean solidification

Author

Miljković, K., Wieczorek, M. A., Laneuville, M., Nemchin, A., Bland, P. A., and Zuber, M. T.

Published

2021

8. Timing of geological events in the lunar highlands recorded in shocked zircon-bearing clasts from Apollo 16

Author

K. H. Joy, J. F. Snape, A. A. Nemchin, R. Tartèse, D. M. Martin, M. J. Whitehouse, V. Vishnyakov, J. F. Pernet-Fisher, and D. A. Kring

Subjects

zircon, lunar samples, apollo 16, regolith breccias, pb-pb age dating, shock-zircon, Science

Abstract

Apollo 16 soil-like regolith breccia 65745,7 contains two zircon-bearing clasts. One of these clasts is a thermally annealed silica-rich rock, which mineralogically has affinities with the High Alkali Suite (Clast 1), and yields zircon dates ranging from 4.08 to 3.38 Ga. The other clast is a KREEP-rich impact melt breccia (Clast 2) and yields zircon dates ranging from 3.97 to 3.91 Ga. The crystalline cores of both grains, which yield dates of ca 3.9 Ga, have undergone shock pressure modification at less than 20 GPa. We interpret that the U-Pb chronometer in these zircon grains has been partially reset by the Imbrium basin-forming event when the clasts were incorporated into the Cayley Plains ejecta blanket deposit. The zircon grains in Clast 1 have been partially decomposed, resulting in a breakdown polymineralic texture, with elevated U, Pb and Th abundances compared with those in the crystalline zircon. These decomposed areas exhibit younger dates around 3.4 Ga, suggesting a secondary high-pressure, high-temperature event, probably caused by an impact in the local Apollo 16 highlands area.

Published

2020

9. Experimental constraints on the long-lived radiogenic isotope evolution of the Moon

Author

Joshua F. Snape, Alexander A. Nemchin, Tim Johnson, Stefanie Luginbühl, Jasper Berndt, Stephan Klemme, Laura J. Morrissey, Wim van Westrenen, Snape, Joshua F, Nemchin, Alexander A, Johnson, Tim, Luginbühl, Stefanie, Berndt, Jasper, Klemme, Stephan, Morrissey, Laura J, van Westrenen, Wim, Geology and Geochemistry, and Earth Sciences

Subjects

lunar magma ocean, radiogenic isotopes, Geochemistry and Petrology, Lunar geochemistry, lunar geochemistry, Lunar Magma Ocean, SDG 14 - Life Below Water, planetary evolution, Planetary evolution, Radiogenic isotopes

Abstract

This study presents the results of high pressure and temperature experiments to investigate the mineral–melt trace element partitioning behaviour for minerals predicted to have formed during the crystallisation of the Lunar Magma Ocean (LMO). The focus of this work has been particularly on determining partition coefficients for parent–daughter pairs of radiogenic elements, for LMO-relevant temperatures, pressures and compositions. The new experimental data are compared with previous studies for the same minerals and elements in order to establish best estimates for the partition coefficient of each element for evolving compositions of minerals as predicted in recent studies modelling LMO crystallisation. These estimates are used to calculate evolving parent–daughter ratios in the LMO residual melt and crystallising minerals for the four main long-lived radiogenic isotope systems that have been studied in lunar samples (Rb–Sr, Sm–Nd, Lu–Hf and U–Pb). The calculated 87Rb/86Sr, 147Sm/144Nd, and 176Lu/177Hf ratios are consistent with predictions for the mantle sources of lunar basalts and evolved lithologies. In contrast, it is difficult to explain the wide range of 238U/204Pb source ratios predicted from the Pb isotopic compositions of basaltic lunar samples. Potential explanations for this observation are discussed, with the conclusion that the Moon most likely experienced a significant loss of volatiles (including Pb), towards the end of LMO crystallisation, resulting in the dramatic U–Pb fractionation evidenced by recent sample analyses.

Published

2022

10. U-Pb Age and Hf Isotope Systematics of Zircon from Eclogite Xenoliths in Devonian Kimberlites: Preliminary Data on the Archaean Roots in the Junction Zone between the Sarmatian and Fennoscandian Segments of the East European Platform

Author

Leonid Shumlyanskyy, Stepan Tsymbal, Monika A. Kusiak, Simon A. Wilde, Alexander A. Nemchin, Iryna Tarasko, Liudmyla Shumlianska, and Mandy Hofmann

Subjects

eclogite xenolith, kimberlite, zircon, U–Pb age, Hf isotopes, Ukrainian Shield, Geology, QE1-996.5

Abstract

The results of a laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) U–Pb dating and a Hf isotope study of zircon crystals separated from small eclogite xenoliths found in Devonian kimberlites within the Prypyat horst, Ukraine, have been reported. The studied area is located in the junction zone between the Sarmatian and Fennoscandian segments of the East European Platform. Four laser ablation sites on two zircon grains yielded Paleoproterozoic U–Pb ages between 1954 ± 24 and 1735 ± 54 Ma. In contrast, three of four Hf sites revealed negative εHf values and Paleoarchean to Mesoarchean model ages, excluding the possibility that the eclogite xenoliths represented segments of a juvenile Paleoproterozoic subducted slab or younger mafic melts crystallized in the subcontinental lithospheric mantle. A single laser ablation Hf spot yielded a positive εHf value (+3) and a Paleoproterozoic model age. Two models for eclogite origin can be proposed. The first foresees the extension of the Archean lower-crustal or lithospheric roots beneath the Sarmatia–Fennoscandia junction zone for over 200 km from the nearest known outcrop of Archean rocks in the Ukrainian Shield. The second model is that the Central Belarus Suture Zone represents a rifted-out fragment of the Kola–Karelian craton that was accreted to Sarmatia before the actual collision of these two segments of Baltica.

Published

2021

11. Evidence for extremely rapid magma ocean crystallization and crust formation on Mars

Author

Bouvier, Laura C., Costa, Maria M., Connelly, James N., Jensen, Ninna K., Wielandt, Daniel, Storey, Michael, Nemchin, Alexander A., Whitehouse, Martin J., Snape, Joshua F., Bellucci, Jeremy J., Moynier, Frédéric, Agranier, Arnaud, Gueguen, Bleuenn, Schönbächler, Maria, and Bizzarro, Martin

Published

2018

12. CO2 fluid inclusions in Jack Hills zircons

Author

Menneken, Martina, Geisler, Thorsten, Nemchin, Alexander A., Whitehouse, Martin J., Wilde, Simon A., Gasharova, Biliana, and Pidgeon, Robert T.

Published

2017

13. Microstructural constraints on the mechanisms of the transformation to reidite in naturally shocked zircon

Author

Erickson, Timmons M., Pearce, Mark A., Reddy, Steven M., Timms, Nicholas E., Cavosie, Aaron J., Bourdet, Julien, Rickard, William D. A., and Nemchin, Alexander A.

Published

2017

14. Constraining the formation and transport of lunar impact glasses using the ages and chemical compositions of Chang’e-5 glass beads

Author

Tao Long, Yuqi Qian, Marc D. Norman, Katarina Miljkovic, Carolyn Crow, James W. Head, Xiaochao Che, Romain Tartèse, Nicolle Zellner, Xuefeng Yu, Shiwen Xie, Martin Whitehouse, Katherine H. Joy, Clive R. Neal, Joshua F. Snape, Guisheng Zhou, Shoujie Liu, Chun Yang, Zhiqing Yang, Chen Wang, Long Xiao, Dunyi Liu, and Alexander Nemchin

Subjects

Multidisciplinary

Abstract

Impact glasses found in lunar soils provide a possible window into the impact history of the inner solar system. However, their use for precise reconstruction of this history is limited by an incomplete understanding of the physical mechanisms responsible for their origin and distribution and possible relationships to local and regional geology. Here, we report U-Pb isotopic dates and chemical compositions of impact glasses from the Chang’e-5 soil and quantitative models of impact melt formation and ejection that account for the compositions of these glasses. The predominantly local provenance indicated by their compositions, which constrains transport distances to

Published

2022

15. Constraining the formation and transport of lunar impact glasses using the ages and chemical compositions of Chang’e-5 glass beads

Author

Long, Tao, primary, Qian, Yuqi, additional, Norman, Marc D., additional, Miljkovic, Katarina, additional, Crow, Carolyn, additional, Head, James W., additional, Che, Xiaochao, additional, Tartèse, Romain, additional, Zellner, Nicolle, additional, Yu, Xuefeng, additional, Xie, Shiwen, additional, Whitehouse, Martin, additional, Joy, Katherine H., additional, Neal, Clive R., additional, Snape, Joshua F., additional, Zhou, Guisheng, additional, Liu, Shoujie, additional, Yang, Chun, additional, Yang, Zhiqing, additional, Wang, Chen, additional, Xiao, Long, additional, Liu, Dunyi, additional, and Nemchin, Alexander, additional

Published

2022

16. The U-Pb Zircon Geochronology (LA-ICP-MS) of Geological Processes in Granulites of Middle Bouh Area. Article 3. Rock association in the lower reaches of the Yatran river

Author

L.M. Stepanyuk, V.O. Syomka, Leonid Shumlyanskyy, S.A. Wilde, S.M. Bondarenko, S.I. Kurylo, and A.A. Nemchin

Subjects

010506 paleontology, La icp ms, Geochronology, Geochemistry, 010502 geochemistry & geophysics, Granulite, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Zircon

Abstract

LA-ICP-MS method was applied to investigate U-Pb and Lu-Hf isotope systematics of zircon crystals from charnockitic gneiss and biotite-garnet-hypersthene enderbite that occur in the lower reaches of the Yatran river (Yatran block of the Bouh river area). According to the obtained isotope data, charnockitic gneiss hosts three zircon populations. The oldest one is represented by three crystals that have isotope age between 3125 and 3300 Ma, and εHf values between –2.3 and –7.5. The next population is well-defined, it has an age of 2038±25 Ma and large variations of Hf isotope composition: 176Hf/177Hf — from 0.28122 to 0.28261, εHf — from –9.3 до 4.6. However, the ages of most of the analyzed zircons spread along the concordia between 2300 and 2800 Ma. All zircons in this population have a similar Hf isotope composition 176Hf/177Hf = 0.28072 to 0.28092, which does not depend on the age. It is characteristic that the oldest (with preserved U-Pb isotope systematics) crystals have positive or slightly negative εHf values. Most of the U-Pb isotope analyses of zircons from enderbite fall on the discordia line that has an upper interception age of 2029 ± 18 Ma. A small number of discordant grains have 207Pb/206Pb ages up to 2500 Ma. Hafnium isotope composition in zircons from enderbite varies widely: 176Hf/177Hf = 0.28131 to 0.28151, and εHf from –6.2 to 1.8.

Published

2021

17. Calibrating volatile loss from the Moon using the U-Pb system

Author

Connelly, J. N., Nemchin, A. A., Merle, Renaud E., Snape, J. F., Whitehouse, M. J., Bizzarro, M., Connelly, J. N., Nemchin, A. A., Merle, Renaud E., Snape, J. F., Whitehouse, M. J., and Bizzarro, M.

Abstract

Previous isotope studies of lunar samples have demonstrated that volatile loss was an important part of the early history of the Moon. The radiogenic U-Pb system, where Pb has a significantly lower T50% condensation temperature than U, has the capacity to both recognize and calibrate the extent of volatile loss but this approach has been hindered by terrestrial Pb contamination of samples. We employ a novel method that integrates analyses of individual samples by Ion Microprobe and Thermal Ionization mass spectrometry to correct for ubiquitous common Pb contamination, a method that results in significantly higher estimates for mu-values (238U/204Pb) than previously reported. Using this method, six of seven samples of low-Ti basaltic meteorites return mu-values between 1900 and 9600, values that are consistent with a re-evaluation of published results that return mu-values of 510-2900 for both low-and high-Ti basalts. While some degree of fractionation during partial melting may increase mu-values, we infer that the source region(s) for the basalts must also have had elevated mu-values by the time the lunar magma ocean solidified. Models to account for the available initial Pb isotopic compositions of lunar basalts in light of timing constraints from thermal modelling imply that their source regions had a mu-value of at least 280, consistent with the elevated mu-values of lunar basalts and that inferred for their sources. Such high mu-values are attributed to the preferential loss of more than 99% of the Pb over U relative to a precursor with a Mars-like composition in the aftermath of the giant impact. Such an extensive loss of Pb is consistent with previously reported losses of other elements with comparable volatility, namely Zn, Rb, Ga and CrO2. Finally, our modelling of highly-radiogenic lunar Pb isotopes assuming crystallization of the lunar magma ocean over 100s of millions of years shows that the elevated mu-values allows for, but does not require, a young Mo

Published

2022

18. A micrometeorite from a stony asteroid identified in Luna 16 soil

Author

Demidova, S. , I, Whitehouse, M. J., Merle, Renaud E., Nemchin, A. A., Kenny, G. G., Brandstatter, F., Ntaflos, Th, Dobryden, I, Demidova, S. , I, Whitehouse, M. J., Merle, Renaud E., Nemchin, A. A., Kenny, G. G., Brandstatter, F., Ntaflos, Th, and Dobryden, I

Abstract

Despite the intense cratering history of the Moon, very few traces of meteoritic material have been identified in the more than 380 kg of samples returned to Earth by the Apollo and Luna missions. Here we show that an similar to 200-mu m-sized fragment collected by the Luna 16 mission has extra-lunar origins and probably originates from an LL chondrite with similar properties to near-Earth stony asteroids. The fragment has not experienced temperatures higher than 400 degrees C since its protolith formed early in the history of the Solar System. It arrived on the Moon, either as a micrometeorite or as the result of the break-up of a bigger impact, no earlier than 3.4 Gyr ago and possibly around 1Gyr ago, an age that would be consistent with impact ages inferred from basaltic fragments in the Luna 16 sample and of a known dynamic upheaval in the Flora asteroid family, which is thought to be the source of L and LL chondrite meteorites. These results highlight the importance of extra-lunar fragments in constraining the impact history of the Earth-Moon system and suggest that material from LL chondrite asteroids may be an important component.

Published

2022

19. U-Pb isotope systematics and impact ages recorded by a chemically diverse population of glasses from an Apollo 14 lunar soil

Author

Nemchin, A. A., Norman, M. D., Grange, M. L., Zeigler, R. A., Whitehouse, M. J., Muhling, J. R., Merle, Renaud E., Nemchin, A. A., Norman, M. D., Grange, M. L., Zeigler, R. A., Whitehouse, M. J., Muhling, J. R., and Merle, Renaud E.

Abstract

Glass beads formed by ejection of impact-melted lunar rocks and soils are an important component of lunar soils. These glasses range from 100s of microns to up to a few cm in diameter and contain variable, but usually relatively low (several hundred ppb to a few ppm), quantities of U. Because Pb is a volatile element, it tends to be lost from the melts, so individual impact glasses can be dated by the U-Th-Pb isotopic systems. The presence of two additional Pb components in lunar glasses, likely linked to addition of lunar Pb to the beads during their residence on the lunar surface and from terrestrial laboratory contamination, require corrections to the data before accurate formation ages of the glasses can be determined. Here we report a U-Th-Pb isotopic and geochemical study of impact glasses from the Apollo 14 soil 14163, which documents multiple impacts into chemically diverse targets that can be linked to the main groups of rocks found on the Moon, i.e., mare basalts, highlands plagioclase-rich rocks, and KREEP (from high contents of K, REE and P) enriched rocks. The impact ages show a bimodal distribution with peaks at ~3500-3700 Ma and < 1000 Ma, similar to that obtained previously by Ar-40-Ar-39 dating of other suites of lunar regolith glasses. Our data suggest two predominant age peaks at ~100 Ma and ~500 Ma, with other statistically definable clusters of ages also possible. As Pb is relatively resistant to subsolidus diffusive loss in these glasses, the age clusters probably represent primary formation ages during impact events, although processes such as preferential preservation of young glasses and impact conditions necessary for production of regolith glasses need further quantification. (C) 2021 The Authors. Published by Elsevier Ltd.

Published

2022

20. Constraining the formation and transport of lunar impact glasses using the ages and chemical compositions of Chang’e-5 glass beads

Author

Long, T., Qian, Y., Norman, M.D., Miljković, Katarina, Crow, C., Head, J.W., Che, X., Tartèse, R., Zellner, N., Yu, X., Xie, S., Whitehouse, M., Joy, K.H., Neal, C.R., Snape, J.F., Zhou, G., Liu, S., Yang, C., Yang, Z., Wang, C., Xiao, L., Liu, D., Nemchin, Alexander, Long, T., Qian, Y., Norman, M.D., Miljković, Katarina, Crow, C., Head, J.W., Che, X., Tartèse, R., Zellner, N., Yu, X., Xie, S., Whitehouse, M., Joy, K.H., Neal, C.R., Snape, J.F., Zhou, G., Liu, S., Yang, C., Yang, Z., Wang, C., Xiao, L., Liu, D., and Nemchin, Alexander

Abstract

Impact glasses found in lunar soils provide a possible window into the impact history of the inner solar system. However, their use for precise reconstruction of this history is limited by an incomplete understanding of the physical mechanisms responsible for their origin and distribution and possible relationships to local and regional geology. Here, we report U-Pb isotopic dates and chemical compositions of impact glasses from the Chang’e-5 soil and quantitative models of impact melt formation and ejection that account for the compositions of these glasses. The predominantly local provenance indicated by their compositions, which constrains transport distances to <~150 kilometers, and the age-frequency distribution are consistent with formation mainly in impact craters 1 to 5 kilometers in diameter. Based on geological mapping and impact cratering theory, we tentatively identify specific craters on the basaltic unit sampled by Chang’e-5 that may have produced these glasses and compare their ages with the impact record of the asteroid belt.

Published

2022

21. Timing of geological events in the lunar highlands recorded in shocked zircon-bearing clasts from Apollo 16

Author

Joshua F. Snape, D.M. Martin, John F. Pernet-Fisher, David A. Kring, Alexander A. Nemchin, Romain Tartèse, Martin J. Whitehouse, Vladimir Vishnyakov, Katherine H. Joy, and Geology and Geochemistry

Subjects

010504 meteorology & atmospheric sciences, apollo 16, Astronomy, Apollo, Geochemistry, shock-zircon, zircon, 010502 geochemistry & geophysics, 01 natural sciences, Texture (geology), Breccia, lcsh:Science, regolith breccias, 0105 earth and related environmental sciences, Multidisciplinary, lunar samples, biology, biology.organism_classification, Regolith, pb-pb age dating, Geology of the Moon, 13. Climate action, Clastic rock, Ejecta blanket, lcsh:Q, Geology, Research Article, Zircon

Abstract

Apollo 16 soil-like regolith breccia 65745,7 contains two zircon-bearing clasts. One of these clasts is a thermally annealed silica-rich rock, which mineralogically has affinities with the High Alkali Suite (Clast 1), and yields zircon dates ranging from 4.08 to 3.38 Ga. The other clast is a KREEP-rich impact melt breccia (Clast 2) and yields zircon dates ranging from 3.97 to 3.91 Ga. The crystalline cores of both grains, which yield dates ofca3.9 Ga, have undergone shock pressure modification at less than 20 GPa. We interpret that the U-Pb chronometer in these zircon grains has been partially reset by the Imbrium basin-forming event when the clasts were incorporated into the Cayley Plains ejecta blanket deposit. The zircon grains in Clast 1 have been partially decomposed, resulting in a breakdown polymineralic texture, with elevated U, Pb and Th abundances compared with those in the crystalline zircon. These decomposed areas exhibit younger dates around 3.4 Ga, suggesting a secondary high-pressure, high-temperature event, probably caused by an impact in the local Apollo 16 highlands area.

Published

2020

22. The internal structure and geodynamics of Mars inferred from a 4.2-Gyr zircon record

Author

Zhengbin Deng, Laura C. Bouvier, Jussi Petteri Suuronen, Tim E. Johnson, Arnaud Agranier, Martin Bizzarro, Laure Martin, Frédéric Moynier, M. M. Costa, Alexander A. Nemchin, Takashi Mikouchi, James N. Connelly, Ninna K. Jensen, Matthew S.A. Horstwood, Centre for Star and Planet Formation (STARPLAN), Globe Institute, Faculty of Health and Medical Sciences, University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH)-Faculty of Health and Medical Sciences, University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH), British Geological Survey (BGS), European Synchroton Radiation Facility [Grenoble] (ESRF), Institut de Physique du Globe de Paris (IPGP (UMR_7154)), Institut national des sciences de l'Univers (INSU - CNRS)-Université de La Réunion (UR)-Institut de Physique du Globe de Paris (IPG Paris)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Laboratoire Géosciences Océan (LGO), Université de Bretagne Sud (UBS)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS), The University of Western Australia (UWA), School of Earth and Planetary Sciences [Perth], Curtin University [Perth], and Planning and Transport Research Centre (PATREC)-Planning and Transport Research Centre (PATREC)

Subjects

Population, Geochemistry, Mars, SYSTEMATICS, zircon, 010502 geochemistry & geophysics, MARTIAN MANTLE, 01 natural sciences, Mantle plume, Mantle (geology), meteorites, AGE, Earth, Atmospheric, and Planetary Sciences, 0103 physical sciences, HISTORY, geodynamics, education, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Martian, education.field_of_study, Multidisciplinary, ORIGIN, MINERALOGY, UAT:1007, Crust, Mars Exploration Program, 13. Climate action, [SDU]Sciences of the Universe [physics], CONVECTION, UAT:1038, Physical Sciences, CRUST, Geology, Geodynamics of Mars, Zircon, MAGMA OCEAN

Abstract

Significance We discovered a zircon record in a Martian meteorite that spans 4.2 Gyr, nearly the entire geologic history of Mars. Ancient zircons define a bimodal distribution with groupings at 4474 ± 10 Ma and 4442 ± 17 Ma, reflecting intense bombardment episodes triggered by the migration of the gas giant planets. A group of younger detrital zircons record ages from 1548.0 ± 8.8 Ma to 299.5 ± 0.6 Ma. The only plausible sources for these grains are the Elysium and Tharsis volcanic provinces that are the expressions of deep-seated mantle plumes. The chondritic-like Hf-isotope compositions of these zircons require the existence of a primitive and convecting mantle reservoir. Thus, these grains provide a tangible record of the deep Martian interior., Combining U–Pb ages with Lu–Hf data in zircon provides insights into the magmatic history of rocky planets. The Northwest Africa (NWA) 7034/7533 meteorites are samples of the southern highlands of Mars containing zircon with ages as old as 4476.3 ± 0.9 Ma, interpreted to reflect reworking of the primordial Martian crust by impacts. We extracted a statistically significant zircon population (n = 57) from NWA 7533 that defines a temporal record spanning 4.2 Gyr. Ancient zircons record ages from 4485.5 ± 2.2 Ma to 4331.0 ± 1.4 Ma, defining a bimodal distribution with groupings at 4474 ± 10 Ma and 4442 ± 17 Ma. We interpret these to represent intense bombardment episodes at the planet’s surface, possibly triggered by the early migration of gas giant planets. The unradiogenic initial Hf-isotope composition of these zircons establishes that Mars’s igneous activity prior to ∼4.3 Ga was limited to impact-related reworking of a chemically enriched, primordial crust. A group of younger detrital zircons record ages from 1548.0 ± 8.8 Ma to 299.5 ± 0.6 Ma. The only plausible sources for these grains are the temporally associated Elysium and Tharsis volcanic provinces that are the expressions of deep-seated mantle plumes. The chondritic-like Hf-isotope compositions of these zircons require the existence of a primitive and convecting mantle reservoir, indicating that Mars has been in a stagnant-lid tectonic regime for most of its history. Our results imply that zircon is ubiquitous on the Martian surface, providing a faithful record of the planet’s magmatic history.

Published

2020

23. Large impact cratering during lunar magma ocean solidification

Author

Maria T. Zuber, Katarina Miljković, Alexander A. Nemchin, M. Laneuville, Phil A. Bland, Mark A. Wieczorek, and Université Côte d'Azur, Observatoire de la Côte d'Azur, CNRS, Laboratoire Lagrange, Nice, France

Subjects

010504 meteorology & atmospheric sciences, Science, General Physics and Astronomy, Flux, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Mantle (geology), Article, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, Impact crater, 0103 physical sciences, Early solar system, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Multidisciplinary, Structural geology, Crust, General Chemistry, Geophysics, Lunar magma ocean, 13. Climate action, Asteroid, Magma ocean, Geology

Abstract

The lunar cratering record is used to constrain the bombardment history of both the Earth and the Moon. However, it is suggested from different perspectives, including impact crater dating, asteroid dynamics, lunar samples, impact basin-forming simulations, and lunar evolution modelling, that the Moon could be missing evidence of its earliest cratering record. Here we report that impact basins formed during the lunar magma ocean solidification should have produced different crater morphologies in comparison to later epochs. A low viscosity layer, mimicking a melt layer, between the crust and mantle could cause the entire impact basin size range to be susceptible to immediate and extreme crustal relaxation forming almost unidentifiable topographic and crustal thickness signatures. Lunar basins formed while the lunar magma ocean was still solidifying may escape detection, which is agreeing with studies that suggest a higher impact flux than previously thought in the earliest epoch of Earth-Moon evolution., Lunar impact basins formed during the magma ocean solidification should have formed almost unidentifiable topographic and crustal thickness signatures, thus may escape detection. This result allows for a higher impact flux in the earliest epoch of Earth-Moon evolution.

Published

2022

24. U-Pb isotope systematics and impact ages recorded by a chemically diverse population of glasses from an Apollo 14 lunar soil

Author

A.A. Nemchin, M.D. Norman, M.L. Grange, R.A. Zeigler, M.J. Whitehouse, J.R. Muhling, and R. Merle

Subjects

Apollo 14, Geochemistry, Geochemistry and Petrology, Impact glasses, Geokemi, Moon, U-Pb ages

Abstract

Glass beads formed by ejection of impact-melted lunar rocks and soils are an important component of lunar soils. These glasses range from 100s of microns to up to a few cm in diameter and contain variable, but usually relatively low (several hundred ppb to a few ppm), quantities of U. Because Pb is a volatile element, it tends to be lost from the melts, so individual impact glasses can be dated by the U-Th-Pb isotopic systems. The presence of two additional Pb components in lunar glasses, likely linked to addition of lunar Pb to the beads during their residence on the lunar surface and from terrestrial laboratory contamination, require corrections to the data before accurate formation ages of the glasses can be determined. Here we report a U-Th-Pb isotopic and geochemical study of impact glasses from the Apollo 14 soil 14163, which documents multiple impacts into chemically diverse targets that can be linked to the main groups of rocks found on the Moon, i.e., mare basalts, highlands plagioclase-rich rocks, and KREEP (from high contents of K, REE and P) enriched rocks. The impact ages show a bimodal distribution with peaks at ~3500-3700 Ma and < 1000 Ma, similar to that obtained previously by Ar-40-Ar-39 dating of other suites of lunar regolith glasses. Our data suggest two predominant age peaks at ~100 Ma and ~500 Ma, with other statistically definable clusters of ages also possible. As Pb is relatively resistant to subsolidus diffusive loss in these glasses, the age clusters probably represent primary formation ages during impact events, although processes such as preferential preservation of young glasses and impact conditions necessary for production of regolith glasses need further quantification. (C) 2021 The Authors. Published by Elsevier Ltd.

Published

2022

25. The phases of the moon: modelling crystallisation of the lunar magma ocean through equilibrium thermodynamics

Author

Nicholas J. Gardiner, Laura J. Morrissey, Joshua F. Snape, Alexander A. Nemchin, Tim E. Johnson, Johnson, TE, Morrissey, LJ, Nemchin, AA, Gardiner, NJ, Snape, JF, University of St Andrews. School of Earth & Environmental Sciences, and Geology and Geochemistry

Subjects

010504 meteorology & atmospheric sciences, Internal structure of the Moon, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), lunar magma ocean, phase equilibrium modelling, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Convective overturn, QB Astronomy, QE, lunar mantle, SDG 14 - Life Below Water, Petrology, Moon, QC, QB, 0105 earth and related environmental sciences, Basalt, DAS, QE Geology, Igneous rock, QC Physics, Geophysics, Lunar magma ocean, Meteorite, lunar basalts, Space and Planetary Science, Lunar phase, Geology

Abstract

Funding: TEJ acknowledges support from the State Key Laboratory for Geological Processes and Mineral Resources, China University of Geosciences, Wuhan (Open Fund GPMR201903 ). We thank J. B. Balta and T. Prissel for their challenging reviews that led to significant improvements in the final version. Despite some 50 years of intense research on samples returned from the Apollo missions and lunar meteorites, along with remote-sensing and Earth-based observations, many questions regarding the formation and evolution of the Moon persist. These include the detailed compositional and density structure of the lunar mantle and the source and petrogenesis of the diverse suite of extrusive and intrusive igneous rocks. There is broad agreement that the primary internal structure of the Moon reflects crystallisation of a lunar magma ocean (LMO), and that an inverted density gradient within the mantle cumulates led to some reorganisation of layers by partial convective overturn. Experimental studies have provided invaluable constraints on crystallisation of the LMO, but are limited by the relatively small number of experiments that can practically be undertaken. Here we use recently-developed thermodynamic models for minerals and melt in the K2O–Na2O–CaO–FeO–MgO–Al2O3–SiO2–TiO2–Cr2O3 system to model crystallisation of a full-moon LMO based on two existing end-member bulk compositions—Taylor Whole-Moon (TWM), and Lunar Primitive Upper Mantle, LPUM—on which many experimental studies have been based. We follow several recent studies in considering equilibrium crystallisation of the first 50 vol.% and fractional crystallisation thereafter. Our results match well with experimental studies, and provide detailed constraints on the major oxide composition, mineralogy and density structure based on the two starting compositions that, while exhibiting some similarities, show important differences. The more fertile TWM composition contains significant quantities of garnet in the deep mantle, whereas the LPUM composition has none. By contrast, prior to any gravitational overturn, the uppermost mantle cumulates for TWM are strongly silica-undersaturated and contain abundant aluminous spinel, whereas those for LPUM are silica-saturated. For both starting compositions, with the exception of TiO2 and Na2O, our modelled compositions of the final dregs of fractionated melt show a reasonable match with existing estimates on the composition of urKREEP. Modelled partial melts of the upper-mantle cumulates at low to moderate melt fractions have major oxide compositions that match well with low- and intermediate-Ti lunar basalts. The correspondence is particularly good for picritic (green) glasses that likely represent melts derived from deeper levels within the upper mantle. The wide spread in TiO2 concentrations in lunar basalts and basaltic glasses is consistent with density-driven reorganisation involving ilmenite. Our simulations provide thermodynamically-robust estimates of the compositional, mineralogical and density structure of the lunar interior that are unprecedented in their detail, and which provide the foundation for several lines of future research addressing the origin and secular evolution of the Moon. Postprint

Published

2021

26. Age and composition of young basalts on the Moon, measured from samples returned by Chang'e-5

Author

Romain Tartèse, Katherine H. Joy, Xiaochao Che, Alexander A. Nemchin, Dapeng Li, C. A. Crow, Zemin Bao, Gretchen Benedix, Fred Jourdan, Zengsheng Li, Chen Wang, James W. Head, Tao Long, Chun Yang, Zhiqing Yang, Bradley L. Jolliff, J. F. Snape, Runlong Fan, Martin J. Whitehouse, Clive R. Neal, Stuart G. Webb, Marc D. Norman, Shiwen Xie, Jianhui Liu, and Dunyi Liu

Subjects

Basalt, geography, Multidisciplinary, geography.geographical_feature_category, chemistry, Volcano, Potassium, Geochemistry, chemistry.chemical_element, Thorium, Composition (visual arts), Uranium, Geology

Abstract

Sample return shows late lunar volcanism Measuring physical samples of Solar System bodies in the laboratory provides more information than is possible from remote sensing alone. In December 2020, the Chang’e-5 mission landed on the Moon, collected samples, and returned them to Earth. Che et al . analyze two fragments of volcanic lunar basalt collected by Chang’e-5. Radiometric dating using lead isotopes indicated that the rocks formed from magma that erupted about 2 billion years ago, later than other volcanic lunar samples. The abundance of extinct radioactive elements in the rock is too low for radioactive heating to have produced the magma. Another, thus far unknown, source must be responsible for the late lunar volcanism. —KTS

Published

2021

27. Age and composition of the youngest basalts on the Moon returned by the Chang’e-5

Author

Che, Xiaochao, Nemchin, Alexander A., Liu, Dunyi, Long, Tao, Wang, Chen, Norman, Marc D., Joy, Katherine, Tartese, Romain, Head, James, Jolliff, Bradley L., Snape, Joshua, Neal, Clive R., Whitehouse, Martin J., Crow, Carolyn, Benedix, Gretchen, Jourdan, Fred, Yang, Zhiqing, Yang, Chun, Liu, Jianhui, Xie, Shiwen, Bao, Zemin, Fan, Runlong, Li, Dapeng, Li, Zengsheng, and Webb, Stuart G.

Abstract

Orbital data indicate that the youngest volcanic units on the Moon are basalt lavas in Oceanus Procellarum, a region with high levels of the heat-producing elements potassium, thorium, and uranium. The Chang’e-5 mission collected samples of these young lunar basalts and returned them to Earth for laboratory analysis. We measure an age of 1963 ± 57 Ma for these lavas and determine their chemical and mineralogical compositions. This age constrains the lunar impact chronology of the inner Solar System and the thermal evolution of the Moon. There is no evidence for high concentrations of heat-producing elements in the deep mantle of the Moon that generated these lavas, so alternate explanations are required for the longevity of lunar magmatism.

Published

2021

28. U-Pb Age and Hf Isotope Systematics of Zircon from Eclogite Xenoliths in Devonian Kimberlites: The Neoarchaean Roots of the Central Belarus Suture Zone

Author

Shumlyanskyy, Leonid, Tsymbal, Stepan, Kusiak, Monika A., Wilde, Simon A., Nemchin, Alexander A., Tarasko, Iryna, Shumlianska, Liudmyla, and Hofmann, Mandy

Subjects

geochemistry_petrology

Abstract

The results of an LA-ICP-MS U-Pb dating and Hf isotope study of zircon crystals separated from small eclogite xenoliths found in Devonian kimberlites within the Prypyat horst, Ukraine, are reported. The studied area is located in the Central Belarusian Suture Zone, which represents a Paleoproterozoic belt extending along the boundary between the Sarmatian and Fennoscandian segments of the East European Platform. Four laser ablation sites on two zircon grains yielded Paleoproterozoic U-Pb ages between 1954 ± 24 Ma and 1735 ± 54 Ma. In contrast, three of four Hf sites revealed negative εHf values and Paleoarchean to Mesoarchean model ages, excluding the possibility that the eclogite xenoliths represent segments of a Paleoproterozoic subducted slab or younger mafic melts crystallized in the subcontinental lithospheric mantle. A single laser ablation Hf spot yielded a positive εHf value (+3) and a Paleoproterozoic model age. Two models for eclogite origin can be proposed. The first foresees the extension of the Archean lower-crustal or lithospheric roots beneath the Central Belarus Suture Zone for over 200 km from the nearest known outcrop of Archean rocks. The second model is that the Central Belarus Suture Zone represents a rifted-out fragment of the Kola-Karelian craton that was accreted to Sarmatia before the actual collision of these two segments of Baltica.

Published

2021

29. U-Pb Age and Hf Isotope Systematics of Zircon from Eclogite Xenoliths in Devonian Kimberlites: Preliminary Data on the Archaean Roots in the Junction Zone between the Sarmatian and Fennoscandian Segments of the East European Platform

Author

Shumlyanskyy, Leonid, primary, Tsymbal, Stepan, additional, Kusiak, Monika A., additional, Wilde, Simon A., additional, Nemchin, Alexander A., additional, Tarasko, Iryna, additional, Shumlianska, Liudmyla, additional, and Hofmann, Mandy, additional

Published

2021

30. Single Zircon Evaporation and SHRIMP Ages for Granulite‐Facies Rocks in the Mozambique Belt of Tanzania

Author

Muhongo, Sospeter, Kröner, Alfred, and Nemchin, A. A.

Published

2001

31. The timing of basaltic volcanism at the Apollo landing sites

Author

Alexander A. Nemchin, Martin J. Whitehouse, Thomas N. Hopkinson, Mahesh Anand, Joshua F. Snape, Renaud E. Merle, and Geology and Geochemistry

Subjects

Basalt, Isochron, Isochron dating, Pb isotopes, 010504 meteorology & atmospheric sciences, biology, Apollo, Geochemistry, Geokemi, Volcanism, 010502 geochemistry & geophysics, biology.organism_classification, chronology, mare basalt, 01 natural sciences, Mantle (geology), Geochemistry and Petrology, lunar volcanism, Geology, 0105 earth and related environmental sciences, Chronology

Abstract

Precise crystallisation ages have been determined for a range of Apollo basalts from Pb-Pb isochrons generated using Secondary Ion Mass Spectrometry (SIMS) analyses of multiple accessory phases including K-feldspar, K-rich glass and phosphates. The samples analysed in this study include five Apollo 11 high-Ti basalts, one Apollo 14 high-Al basalt, seven Apollo 15 low-Ti basalts, and five Apollo 17 high-Ti basalts. Together with the samples analysed in two previous similar studies, Pb-Pb isochron ages have been determined for all of the major basaltic suites sampled during the Apollo missions. The accuracy of these ages has been assessed as part of a thorough review of existing age determinations for Apollo basalts, which reveals a good agreement with previous studies of the same samples, as well as with average ages that have been calculated for the emplacement of the different basaltic suites at the Apollo landing sites. Furthermore, the precision of the new age determinations helps to resolve distinctions between the ages of different basaltic suites in more detail than was previously possible. The proposed ages for the basaltic surface flows at the Apollo landing sites have been reviewed in light of these new sample ages. Finally, the data presented here have also been used to constrain the initial Pb isotopic compositions of the mare basalts, which indicate a significant degree of heterogeneity in the lunar mantle source regions, even among the basalts collected at individual landing sites.

Published

2019

32. U-Pb SIMS ages of Apollo 14 zircon

Author

Martin J. Whitehouse, Alexander A. Nemchin, F. Thiessen, Joshua F. Snape, Chemistry, Analytical, Environmental & Geo-Chemistry, and Geology and Geochemistry

Subjects

U-Pb dating, Geochemistry, KREEP, Poikilitic, zircon, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Impact crater, Space and Planetary Science, Clastic rock, 0103 physical sciences, Magma, Breccia, Ejecta blanket, impact events, Moon, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Zircon

Abstract

U-Pb ages of zircon in four different Apollo 14 breccias (14305, 14306, 14314, and 14321) were obtained by secondary ion mass spectrometry. Some of the analyzed grains occur as cogenetic, poikilitic zircon grains in lithic clasts, revealing magmatic events at ~4286 Ma, ~4200–4220 Ma, and ~4150 Ma. The age distribution of the crystal clasts in the breccias exhibits a minor peak at ~4210 Ma, which can be attributed to a magmatic event, as recorded in zircon grains located in noritic clasts. An age peak at ~4335 Ma is present in all four breccias, as well as zircon grains from different Apollo landing sites, enhancing the confidence that these grains recorded a global zircon-forming event. The overall age distribution among the four breccias exhibits minor differences between the breccias collected farther away from the Cone Crater and the ones collected within the continuous ejecta blanket of the Cone Crater. A granular zircon grain yielded a 207Pb/206Pb age of 3936 ± 8 Ma, which is interpreted as an impact event. A similar age of 3941 ± 5 Ma (n = 17, MSWD = 0.89, P = 0.58) was obtained for a large zircon grain (~430 × 340 μm in size). This grain might have crystallized in the same impact melt sheet which formed the granular zircon or the age is representative of the final extrusion of KREEP magma. The majority of zircon grains, however, occur as isolated crystal clasts within the matrix and their ages cannot be correlated with any real events (impact or magmatic) nor can the possibility be excluded that these ages represent partial resetting of the U-Pb system.

Published

2019

33. The early geological history of the Moon inferred from ancient lunar meteorite Miller Range 13317

Author

Ray Burgess, Katherine H. Joy, Joshua F. Snape, N. M. Curran, Alexander A. Nemchin, Martin J. Whitehouse, Jamie Gilmour, John F. Pernet-Fisher, and Geology and Geochemistry

Subjects

Lunar meteorite, Range (biology), Geokemi, 010502 geochemistry & geophysics, 01 natural sciences, Regolith, Astrobiology, Geochemistry, Geophysics, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Breccia, SDG 14 - Life Below Water, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Miller Range (MIL) 13317 is a heterogeneous basalt-bearing lunar regolith breccia that provides insights into the early magmatic history of the Moon. MIL 13317 is formed from a mixture of material with clasts having an affinity to Apollo ferroan anorthosites and basaltic volcanic rocks. Noble gas data indicate that MIL 13317 was consolidated into a breccia between 2610 ± 780 Ma and 1570 ± 470 Ma where it experienced a complex near-surface irradiation history for ~835 ± 84 Myr, at an average depth of ~30 cm. The fusion crust has an intermediate composition (Al2O3 15.9 wt%; FeO 12.3 wt%) with an added incompatible trace element (Th 5.4 ppm) chemical component. Taking the fusion crust to be indicative of the bulk sample composition, this implies that MIL 13317 originated from a regolith that is associated with a mare-highland boundary that is KREEP-rich (i.e., K, rare earth elements, and P). A comparison of bulk chemical data from MIL 13317 with remote sensing data from the Lunar Prospector orbiter suggests that MIL 13317 likely originated from the northwest region of Oceanus Procellarum, east of Mare Nubium, or at the eastern edge of Mare Frigoris. All these potential source areas are on the near side of the Moon, indicating a close association with the Procellarum KREEP Terrane. Basalt clasts in MIL 13317 are from a very low-Ti to low-Ti (between 0.14 and 0.32 wt%) source region. The similar mineral fractionation trends of the different basalt clasts in the sample suggest they are comagmatic in origin. Zircon-bearing phases and Ca-phosphate grains in basalt clasts and matrix grains yield 207Pb/206Pb ages between 4344 ± 4 and 4333 ± 5 Ma. These ancient 207Pb/206Pb ages indicate that the meteorite has sampled a range of Pre-Nectarian volcanic rocks that are poorly represented in the Apollo, Luna, and lunar meteorite collections. As such, MIL 13317 adds to the growing evidence that basaltic volcanic activity on the Moon started as early as ~4340 Ma, before the main period of lunar mare basalt volcanism at ~3850 Ma.

Published

2019

34. Shock-deformed zircon from the Chicxulub impact crater and implications for cratering process

Author

Zhao, Jiawei, Xiao, Long, Xiao, Zhiyong, Morgan, Joanna, Osinski, Gordon, Neal, Clive, Gulick, Sean P.S., Riller, Ulrich, Claeys, Philippe, Zhao, Shanrong, Prieur, Nils, Nemchin, Alexander, Yu, Shuoran, Chenot, Elise, Christeson, Gail l., Cockell, Charles S., Coolen, Marco J.L., Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Jones, Heather, Kring, David A., LOFI, Johanna, Lowery, Christopher M., OCAMPO-TORRES, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Sato, Honami, Smit, Jan, Tikoo-Schantz, Sonia M., Tomioka, Naotaka, Urrutia Fucugauchi, Jaime, Whalen, Michael T., Wittmann, Axel, Yamaguchi, Kosei E., Institut de chimie et procédés pour l'énergie, l'environnement et la santé (ICPEES), Université de Strasbourg (UNISTRA)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Natural Environment Research Council (NERC), Analytical, Environmental & Geo-Chemistry, Earth System Sciences, and Chemistry

Subjects

Geochemistry & Geophysics, Reidite, 010504 meteorology & atmospheric sciences, 04 Earth Sciences, Geology, zircon, 010502 geochemistry & geophysics, 01 natural sciences, Shock (mechanics), Shock metamorphism, Impact crater, 13. Climate action, [SDU]Sciences of the Universe [physics], Scientific method, microstructures, shock metamorphism, Petrology, Cratering, 0105 earth and related environmental sciences, Zircon

Abstract

International audience; Large impact structures with peak rings are common landforms across the solar system, and their formation has implications for both the interior structure and thermal evolution of planetary bodies. Numerical modeling and structural studies have been used to simulate and ground truth peak-ring formative mechanisms, but the shock metamorphic record of minerals within these structures remains to be ascertained. We investigated impact-related microstructures and high-pressure phases in zircon from melt-bearing breccias, impact melt rock, and granitoid basement from the Chicxulub peak ring (Yucatán Peninsula, Mexico), sampled by the International Ocean Discovery Program (IODP)/International Continental Drilling Project (IODP-ICDP) Expedition 364 Hole M0077A. Zircon grains exhibit shock features such as reidite, zircon twins, and granular zircon including “former reidite in granular neoblastic” (FRIGN) zircon. These features record an initial high-pressure shock wave (>30 GPa), subsequent relaxation during the passage of the rarefaction wave, and a final heating and annealing stage. Our observed grain-scale deformation history agrees well with the stress fields predicted by the dynamic collapse model, as the central uplift collapsed downward-then-outward to form the peak ring. The occurrence of reidite in a large impact basin on Earth represents the first such discovery, preserved due to its separation from impact melt and rapid cooling by the resurging ocean. The coexistence of reidite and FRIGN zircon within the impact melt–bearing breccias indicates that cooling by seawater was heterogeneous. Our results provide valuable information on when different shock microstructures form and how they are modified according to their position in the impact structure, and this study further improves on the use of shock barometry as a diagnostic tool in understanding the cratering process.

Published

2021

35. Origin and age of the earliest Martian crust from meteorite NWA 7533

Author

Humayun, M., Nemchin, A., Zanda, B., Hewins, R.H., Grange, M., Kennedy, A., Lorand, J.-P., Gopel, C., Fieni, C., Pont, S., and Deldicque, D.

Subjects

Astrogeology -- Research, Meteorites -- Properties -- Origin, Mars (Planet) -- Natural history, Breccia -- Properties -- Origin, Earth -- Crust, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

The ancient cratered terrain of the southern highlands of Mars is thought to hold clues to the planet's early differentiation (1,2), but until now no meteoritic regolith breccias have been recovered from Mars. Here we show that the meteorite Northwest Africa (NWA) 7533 (paired with meteorite NWA 7034 (3)) is a polymict breccia consisting of a fine-grained interclast matrix containing clasts of igneous-textured rocks and fine-grained clast-laden impact melt rocks. High abundances of meteoritic siderophiles (for example nickel and iridium) found throughout the rock reach a level in the fine-grained portions equivalent to 5 per cent CI chondritic input, which is comparable to the highest levels found in lunar breccias. Furthermore, analyses of three leucocratic monzonite clasts show a correlation between nickel, iridium and magnesium consistent with differentiation from impact melts. Compositionally, all the fine-grained material is alkalic basalt, chemically identical (except for sulphur, chlorine and zinc) to soils from Gusev crater. Thus, we propose that NWA 7533 is a Martian regolith breccia. It contains zircons for which we measured an age of 4,428 ± 25 million years, which were later disturbed 1,712 ± 85 million years ago. This evidence for early crustal differentiation implies that the Martian crust, and its volatile inventory (4), formed in about the first 100 million years of Martian history, coeval with earliest crust formation on the Moon (5) and the Earth (6). In addition, incompatible element abundances in clast-laden impact melt rocks and interclast matrix provide a geochemical estimate of the average thickness of the Martian crust (50 kilometres) comparable to that estimated geophysically (2,7)., NWA 7533 is a polymict breccia, characterized by a variety of clasts set in a fine-grained (~1 mm) interclast crystalline matrix (ICM) (Fig. 1). The main clast component consists of [...]

Published

2013

36. Interaction of weathering solutions with oxygen and U-Pb isotopic systems of radiation-damaged zircon from an Archean granite, Darling Range Batholith, Western Australia

Author

Pidgeon, R.T., Nemchin, A.A., and Cliff, J.

Subjects

Nuclear radiation, Cratons, Mass spectrometry, Zirconium, Earth sciences

Abstract

Zircons from Archean granites from the Darling Range Batholith in the Yilgarn Craton of Western Australia have been shown to have complexly discordant U-Pb systems with a strong component of zero age disturbance. The only geological event that has affected the granites in recent times is the pervasive regional weathering. Our aim in this study was to investigate the effects of weathering on the U-Pb and oxygen systems of the zircons, and to this end, we report secondary ion mass spectrometry (SIMS) results of OH, oxygen and U-Pb isotope systems of six typical zircons from a sample of the granite. These results confirmed the presence of OH in highly radiation-damaged parts of the zircons, demonstrating fluid interaction within grains. The presence of OH was accompanied by significant changes in the [sup.18]O/[sup.16]O ratios. The data suggest trends where δ[sup.18]O values in individual grains both increase and decrease with increasing OH. SIMS measurements showed the U-Pb systems are variably and unsystematically discordant in radiation-damaged parts of the zircons, particularly those with elevated OH contents. The complex U-Pb systems are interpreted in terms of multiple disturbance events between 450 and 0 Ma involving low-temperature fluid-induced movement of radiogenic Pb, decoupled from parent U and Th, within the radiation-damaged zircons, together with some Pb loss. Keywords Weathering of zircon * Discordant U-Pb systems * Oxygen isotopes * OH in metamict zircon, Introduction Nemchin and Pidgeon (1997) reported the results of a secondary ion mass spectrometry (SIMS) U-Pb study of zircons from granites from the Archaean Darling Range Batholith in the south-western [...]

Published

2013

37. Isotopic modelling of Archean crustal evolution from comagmatic zircon--apatite pairs

Author

Aaron J. Cavosie, Christopher L. Kirkland, Jack Gillespie, Peter D. Kinny, Derrick Hasterok, Alexander A. Nemchin, and Laure Martin

Subjects

Craton, geography, Felsic, geography.geographical_feature_category, Archean, Geochemistry, Crust, Early Earth, Geology, Zircon, Petrogenesis, Terrane

Abstract

The composition of Earth's early crust is challenging to assess as only a fragmented record remains. As a consequence, deciphering the composition of early crust as a means to understand early processes on our planet often relies on the isotopic composition of resistive minerals. Here we present a new tool for investigating igneous petrogenesis and crustal evolution by combining 87Sr/86Sr measurements of apatite inclusions with U–Pb and Hf isotope analysis of their host zircon crystals. This approach takes advantage of the complementary inverse fractionation behaviour of Rb/Sr and Lu/Hf, and the cogenetic host/inclusion relationship, to link the three isotopic systems and construct an evolution model in triple isotope space. By applying this triple isotope system modelling to Mesoarchean igneous rocks from the Akia terrane in SW Greenland, we reconstruct a bulk SiO2 composition of 63-68 wt% for the precursor source crust and infer an average crustal residence time of 300–350 Ma. Our modelling implicates involvement of intermediate to felsic Paleo-Eoarchean crust in the genesis of voluminous 3.0 Ga magmatic rocks of the Akia terrane, one of the largest components of the Archean North Atlantic Craton. A further outcome of this approach is the ability to place more robust empirical constraints on the Lu/Hf ratio of the precursor crust by comparison of the modelling output to a global whole-rock dataset. The approach in this work provides a template for further application to ancient rocks in order to better understand the evolution of early Earth.

Published

2021

38. Ages of lunar impact breccias: Limits for timing of the Imbrium impact

Author

Nemchin, Alexander, Long, T., Jolliff, B.L., Wan, Y., Snape, J.F., Zeigler, R., Grange, M.L., Liu, D., Whitehouse, M.J., Timms, Nick, Jourdan, Fred, Nemchin, Alexander, Long, T., Jolliff, B.L., Wan, Y., Snape, J.F., Zeigler, R., Grange, M.L., Liu, D., Whitehouse, M.J., Timms, Nick, and Jourdan, Fred

Abstract

Since the Apollo 14 mission delivered samples of the Fra Mauro formation, interpreted as ejecta of the Imbrium impact, defining the age of this impact has emerged as one of the critical tasks required for the complete understanding of the asteroid bombardment history of the Moon and, by extension, the inner Solar System. Significant effort dedicated to this task has resulted in a substantial set of ages centered around 3.9 Ga and obtained for the samples from most Apollo landing sites using a variety of chronological methods. However, the available age data are scattered over a range of a few tens of millions of years, which hinders the ability to distinguish between the samples that are truly representative of the Imbrium impact and those formed/reset by other, broadly contemporaneous impact events. This study presents a new set of U-Pb ages obtained for the VHK (very high K) basalt clasts found in the Apollo 14 breccia sample 14305 and phosphates from (i) several fragments of impact-melt breccia extracted from Apollo 14 soil sample 14161, and (ii) two Apollo 15 breccias 15455 and 15445. The new data obtained for the Apollo 14 samples increase the number of independently dated samples from this landing site to ten. These Apollo 14 samples represent the Fra Mauro formation, which is traditionally viewed as Imbrium ejecta, and therefore should record the age of the Imbrium impact. Using the variance of ten ages, we propose an age of 3922 ± 12 Ma for this event. Samples that yield ages within these limits can be considered as possible products of the Imbrium impact, while those that fall significantly outside this range should be treated as representing different impact events. Comparison of this age for Imbrium (determined from Apollo 14 samples) with the ages of another eleven impact-melt breccia samples collected at four other landing sites and a related lunar meteorite suggests that they can be viewed as part of Imbrium ejecta. Comprehensive review of 40Ar/39Ar ag

Published

2021

39. Large impact cratering during lunar magma ocean solidification

Author

Miljkovic, Katarina, Wieczorek, M.A., Laneuville, M., Nemchin, Alexander, Bland, Phil, Zuber, M.T., Miljkovic, Katarina, Wieczorek, M.A., Laneuville, M., Nemchin, Alexander, Bland, Phil, and Zuber, M.T.

Abstract

The lunar cratering record is used to constrain the bombardment history of both the Earth and the Moon. However, it is suggested from different perspectives, including impact crater dating, asteroid dynamics, lunar samples, impact basin-forming simulations, and lunar evolution modelling, that the Moon could be missing evidence of its earliest cratering record. Here we report that impact basins formed during the lunar magma ocean solidification should have produced different crater morphologies in comparison to later epochs. A low viscosity layer, mimicking a melt layer, between the crust and mantle could cause the entire impact basin size range to be susceptible to immediate and extreme crustal relaxation forming almost unidentifiable topographic and crustal thickness signatures. Lunar basins formed while the lunar magma ocean was still solidifying may escape detection, which is agreeing with studies that suggest a higher impact flux than previously thought in the earliest epoch of Earth-Moon evolution.

Published

2021

40. Large impact cratering during lunar magma ocean solidification

Author

Miljković, K, Wieczorek, MA, Laneuville, M, Nemchin, A, Bland, PA, Zuber, MT, Miljković, K, Wieczorek, MA, Laneuville, M, Nemchin, A, Bland, PA, and Zuber, MT

Abstract

AbstractThe lunar cratering record is used to constrain the bombardment history of both the Earth and the Moon. However, it is suggested from different perspectives, including impact crater dating, asteroid dynamics, lunar samples, impact basin-forming simulations, and lunar evolution modelling, that the Moon could be missing evidence of its earliest cratering record. Here we report that impact basins formed during the lunar magma ocean solidification should have produced different crater morphologies in comparison to later epochs. A low viscosity layer, mimicking a melt layer, between the crust and mantle could cause the entire impact basin size range to be susceptible to immediate and extreme crustal relaxation forming almost unidentifiable topographic and crustal thickness signatures. Lunar basins formed while the lunar magma ocean was still solidifying may escape detection, which is agreeing with studies that suggest a higher impact flux than previously thought in the earliest epoch of Earth-Moon evolution.

Published

2021

41. Large impact cratering during lunar magma ocean solidification

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Miljković, K, Wieczorek, MA, Laneuville, M, Nemchin, A, Bland, PA, Zuber, Maria, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Miljković, K, Wieczorek, MA, Laneuville, M, Nemchin, A, Bland, PA, and Zuber, Maria

Abstract

The lunar cratering record is used to constrain the bombardment history of both the Earth and the Moon. However, it is suggested from different perspectives, including impact crater dating, asteroid dynamics, lunar samples, impact basin-forming simulations, and lunar evolution modelling, that the Moon could be missing evidence of its earliest cratering record. Here we report that impact basins formed during the lunar magma ocean solidification should have produced different crater morphologies in comparison to later epochs. A low viscosity layer, mimicking a melt layer, between the crust and mantle could cause the entire impact basin size range to be susceptible to immediate and extreme crustal relaxation forming almost unidentifiable topographic and crustal thickness signatures. Lunar basins formed while the lunar magma ocean was still solidifying may escape detection, which is agreeing with studies that suggest a higher impact flux than previously thought in the earliest epoch of Earth-Moon evolution.

Published

2021

42. Comparison of structures in zircons from lunar and terrestrial impactites

Author

Pidgeon, R.T., Nemchin, A.A., and Kamo, S.L.

Subjects

Craters -- Research, Lunar geology -- Research, Breccia -- Research, Zirconium -- Properties -- Research, Earth sciences

Abstract

There have been a number of reports of the presence of shock features, such as planar fracturing and granulation, the transformation of zircon to reidite, and the breakdown of zircon to baddeleyite in zircons associated with terrestrial impacts. It has also been proposed that the progressive development of these shock features, and the degree of disturbance of the zircon U-Pb isotopic system, could be used as a qualitative measure of the shock pressures and post-shock temperatures of the impact. Such behaviour of zircon from terrestrial impacts could be potentially useful in interpreting structures and U-Pb isotopic behaviour of shocked zircons from lunar impactites. However, careful examination of over one hundred zircon grains from samples of lunar breccias from Apollo 14 and 17 have not revealed any grains with terrestrial-like shock features, such as planar deformation features (PDFs), and we have not observed the high-pressure zircon phases reidite or the breakdown of zircon to baddeleyite in zircon grains from the breccias. Most lunar zircon grains show no evidence of a disturbance of their U-Pb systems. However, we have identified a few zircons from lunar breccias that have characteristic internal structures and accompanying Pb loss that we attribute to extreme shock. These structures differ from shock features reported for zircons associated with terrestrial impacts. Whether terrestrial-like impact features were present in the lunar zircons and have been removed during transport and heating in the impact ejecta, or whether these features never developed in the first place, has not been resolved. De nombreux rapports signalent la presence de structures produites par un choc, par exemple des fractures planaires et de la granulation, la transformation de zircon en reidite et la degradation du zircon en baddeleyite dans des zircons associes a des impacts terrestres. Il a aussi ete propose que le developpement progressif de ces structures produites par un choc et le degre de perturbation au systeme isotopique U-Pb puissent etre utilises en tant que mesure qualitative des pressions de choc et des temperatures post-choc de l'impact. Un tel comportement du zircon a la suite d'impacts terrestres pourrait potentiellement servir dans l'interpretation des structures et du comportement isotopique des zircons ayant subi le choc d'impactites lunaires. Toutefois, un examen soigne de plus de cent grains de zircon provenant de breches lunaires d'Apollo 14 et 17 n'a pas reveke de grains avec des caracteristiques de choc de type terrestre, tels que les caracteeristiques de deformation planaire (PDF), et nous n'avons pas observe les phases reidite de haute pression ni la degradation du zircon en baddeleyite dans les grains de zircon provenant des breches. La plupart des grains de zircon lunaire ne montrent aucune evidence de perturbation de leurs systemes U-Pb. Nous avons toutefois identified quelques zircons provenant de breeches lunaires qui possedent les structures internes caracteristiques et la perte associee de Pb que nous attribuons a un choc extreme. Ces structures different des caracteristiques de choc rapportees pour des zircons associes aux impacts terrestres. Il n'a pas ete resolu si les caracteristiques d'impact de type terrestre etaient presentes dans les zircons lunaires et ont ete retirees durant le transport et l'echauffement dans l'ejecta d'impact ou si ces caracteristiques ne se sont jamais developpees., Introduction One of the many interests of Tom Krogh has been the effects of shock metamorphism on the development of microstructures and the stability of the U-Pb systems of zircons [...]

Published

2011

43. Distribution of rare earth elements in lunar zircon

Author

Nemchin, A.A., Grange, M.L., and Pidgeon, R.T.

Subjects

Zircon -- Properties, Breccia -- Properties, Lunar mineralogy -- Research, Rare earth metals -- Properties, Crystallization -- Observations, Earth sciences

Abstract

An investigation of rare earth elements (REE) in 15 zircon grains from lunar breccia sample 14321, combined with published analyses, has allowed lunar zircon grains to be separated into four distinctive types. Type-1 zircon is characterized by the relative depletion of light REE (LREE) resulting in a steep chondrite-normalized pattern. Type-2 zircon shows relative enrichment in the LREE compared to type-1 grains. Type-3 zircon also shows relatively high concentrations of LREE as well as a relative depletion in the heavy REE (HREE), which results in a relatively flat chondrite-normalized pattern. Type-4 zircon grains are characterized by the steepest chondrite-normalized REE pattern, with the lowest LREE and the highest HREE as well as by a distinctive positive Ce anomaly. Multiple analyses of REE in a complex impact modified zircon from breccia sample 73235 suggest a possibility that the very light REE from La to Nd were mobilized during impact. However, the main differences between the identified zircon types appear to be primary and reflect the original crystallization environment of zircon grains. These differences are not linked to major changes associated with the different suites of plutonic rocks, such as Mg- and alkali-suites, and quartz monzodiorites (QMD), but instead reflect small-scale variations in residual pockets of melt where zircon grains crystallized. For example, the presence of plagioclase in the immediate vicinity of zircon was responsible for the type-1 zircon REE pattern, whereas type-2 zircon was formed in the presence of pyroxene. The only exception is type-4 zircon, which was probably associated with some felsite and 'granite' samples representing very late differentiates of lunar mafic magmas. Keywords: Moon, zircon, REE, lunar breccias DOI: 10.2138/am.2010.3297

Published

2010

44. Sr, Nd, Pb and Os Isotope Systematics of CAMP Tholeiites from Eastern North America (ENA): Evidence of a Subduction-enriched Mantle Source

Author

Merle, Renaud, Marzoli, Andrea, Reisberg, Laurie, Bertrand, Hervé, Nemchin, Alexander, Chiaradia, Massimo, Callegaro, Sara, Jourdan, Fred, Bellieni, Giuliano, Kontak, Dan, Puffer, John, and McHone, J. Gregory

Published

2014

45. Pb‐Pb ages and initial Pb isotopic composition of lunar meteorites: NWA 773 clan, NWA 4734, and Dhofar 287

Author

Joshua F. Snape, Renaud E. Merle, Martin J. Whitehouse, Martin Bizzarro, Jeremy J. Bellucci, Gavin G. Kenny, James N. Connelly, Alexander A. Nemchin, and Geology and Geochemistry

Subjects

SM-ND, U-TH-PB, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Article, NORTHWEST AFRICA 773, Mantle (geology), MILLER RANGE 05035, LAPAZ ICEFIELD, MAGMATIC EVOLUTION, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Basalt, RB-SR, TRACE-ELEMENT, MARE BASALTS, Isotopic composition, Geophysics, Meteorite, 13. Climate action, Space and Planetary Science, URANIUM-LEAD SYSTEMATICS, Mafic, Geology

Abstract

Constraining the duration of magmatic activity on the Moon is essential to understand how the lunar mantle evolved chemically through time. Determining age and initial isotopic compositions of mafic lunar meteorites is a critical step in defining the periods of magmatic activity that occurred during the history of the Moon and to constrain the chemical characteristics of mantle components involved in the sources of the magmas. We have used the in situ Pb-Pb SIMS technique to investigate eight lunar gabbros and basalts, including six meteorites from the Northwest Africa (NWA) 773 clan (NWA 2727, NWA 2700, NWA 3333, NWA 2977, NWA 773, and NWA 3170), NWA 4734, and Dhofar 287A. These samples have been selected as there is no clear agreement on their age and they are all from the dominant low titanium chemical group. We have obtained ages of 2981 +/- 12 Ma for NWA 4734 and 3208 +/- 22 Ma for Dhofar 287. For the NWA 773 clan, four samples (the fine-grained basalt NWA 2727 and the three gabbros NWA 773, NWA 2977, NWA 3170) out of six yielded isochron-calculated ages that are identical within uncertainties and yielding an average age of 3086 +/- 5 Ma. The age obtained for the fine-grained basalt NWA 2700 is not precise enough for comparison with the other samples. The gabbroic sample NWA 3333 yielded an age of 3038 +/- 20 Ma suggesting that two distinct magmatic events may be recorded in the meteorites of the NWA 773 clan. The present study aims to identify and assess all potential issues that are associated with different ways to date lunar rocks using U-Pb-based methods. To achieve this, we have compared the new ages with the previously published data set. The entire age data set from lunar mafic meteorites was also screened to identify data showing analytical issues and evidence of resetting and terrestrial contamination. The data set combining the ages of mafic lunar meteorites and Apollo rocks suggests pulses of magmatic activity with two distinct phases between 3950 and 3575 Ma and between 3375 and 3075 Ma with the two phases separated by a gap of approximately 200 Ma. The evolution of the Pb initial ratios of the low-Ti mare basalts between approximately 3400 and 3100 Ma suggests that these rocks were progressively contaminated by a KREEP-like component.

Published

2020

46. The sulfur budget and sulfur isotopic composition of Martian regolith breccia NWA 7533

Author

Jean-Pierre Lorand, Martin J. Whitehouse, Alexander A. Nemchin, Roger H. Hewins, Emilie Thomassot, Claire Rollion-Bard, Munir Humayun, James Farquhar, Jeremy J. Bellucci, Sylvain Courrech du Pont, Jabrane Labidi, Brigitte Zanda, Laboratoire de Planétologie et Géodynamique [UMR 6112] (LPG), Université d'Angers (UA)-Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), Université de Nantes (UN)-Université de Nantes (UN)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Institut de Physique du Globe de Paris (IPGP), Institut national des sciences de l'Univers (INSU - CNRS)-IPG PARIS-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP), Carnegie Institution of Washington, University of Maryland [College Park], University of Maryland System, Centre de Recherches Pétrographiques et Géochimiques (CRPG), Institut national des sciences de l'Univers (INSU - CNRS)-Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), Curtin University [Perth], Planning and Transport Research Centre (PATREC), Swedish Museum of Natural History (NRM), Florida State University [Tallahassee] (FSU), Institut de minéralogie, de physique des matériaux et de cosmochimie (IMPMC), Muséum national d'Histoire naturelle (MNHN)-Institut de recherche pour le développement [IRD] : UR206-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Institut de Physique du Globe de Paris (IPGP (UMR_7154)), Institut national des sciences de l'Univers (INSU - CNRS)-Université de La Réunion (UR)-Institut de Physique du Globe de Paris (IPG Paris)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), and ANR-16-CE31-0012,MARS-PRIME,Environnement Primitif de Mars(2016)

Subjects

chemistry.chemical_classification, 010504 meteorology & atmospheric sciences, Sulfide, Chemistry, chemistry.chemical_element, Mineralogy, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Sulfur, Regolith, Igneous rock, Geophysics, δ34S, 13. Climate action, Space and Planetary Science, [SDU.STU.GC]Sciences of the Universe [physics]/Earth Sciences/Geochemistry, Clastic rock, Breccia, engineering, Pyrite, [SDU.OTHER]Sciences of the Universe [physics]/Other, 0105 earth and related environmental sciences

Abstract

International audience; The sulfur isotope budget of Martian regolith breccia (NWA 7533) has been addressed from conventional fluorination bulk rock analyses and ion microprobe in situ analyses. The bulk rock analyses yield 865 ± 50 ppm S in agreement with LA‐ICP‐MS analyses. These new data support previous estimates of 80% S loss resulting from terrestrial weathering of NWA 7533 pyrite. Pyrite is by far the major S host. Apatite and Fe oxyhydroxides are negligible S carriers, as are the few tiny igneous pyrrhotite–pentlandite sulfide grains included in lithic clasts so far identified. A small nonzero Δ33S (−0.029 ± 0.010‰) signal is clearly resolved at the 2σ level in the bulk rock analyses, coupled with negative CDT‐normalized δ34S (−2.54 ± 0.10‰), and near‐zero Δ36S (0.002 ± 0.09‰). In situ analyses also yield negative Δ33S values (−0.05 to −0.30‰) with only a few positive Δ33S up to +0.38‰. The slight discrepancy compared to the bulk rock results is attributed to a possible sampling bias. The occurrence of mass‐independent fractionation (MIF) supports a model of NWA 7533 pyrite formation from surface sulfur that experienced photochemical reaction(s). The driving force that recycled crustal S in NWA 7533 lithologies—magmatic intrusions or impact‐induced heat—is presently unclear. However, in situ analyses also gave negative δ34S values (+1 to −5.8‰). Such negative values in the hydrothermal setting of NWA 7533 are reflective of hydrothermal sulfides precipitated from H2S/HS‐ aqueous fluid produced via open‐system thermochemical reduction of sulfates at high temperatures (>300 °C).

Published

2020

47. Recrystallization and chemical changes in apatite in response to hypervelocity impact

Author

Kenny, Gavin, Karlsson, Andreas, Schmieder, Martin, Whitehouse, Martin, Nemchin, Alexander, and Bellucci, Jeremy

Subjects

Geology, Geologi, Geosciences, Multidisciplinary, Multidisciplinär geovetenskap

Abstract

Despite the wide utility of apatite, Ca5(PO4)3(F,Cl,OH), in the geosciences, including tracing volatile abundances on the Moon and Mars, little is known about how the mineral responds to the extreme temperatures and pressures associated with hypervelocity impacts. To address this deficiency, we here present the first microstructural analysis and chemical mapping of shocked apatite from a terrestrial impact crater. Apatite grains from the Paasselkä impact structure, Finland, display intragrain crystal-plastic deformation as well as pervasive recrystallization—the first such report in terrestrial apatite. A partially recrystallized grain offers the opportunity to investigate the effect of shock recrystallization on the chemical composition of apatite. The recrystallized portion of the fluorapatite grain is depleted in Mg and Fe relative to the remnant non-recrystallized domain. Strikingly, the recrystallized region alone hosts inclusions of (Mg,Fe)2(PO4)F, wagnerite or a polymorph thereof. These are interpreted to be a product of phase separation during recrystallization and to be related to the reduced abundances of certain elements in the recrystallized domain. The shock-induced recrystallization of apatite, which we show to be related to changes in the mineral’s chemical composition, is not always readily visible in traditional imaging techniques (such as backscattered electron imaging of polished interior surfaces), thus highlighting the need for correlated microstructural, chemical, and isotopic studies of phosphates. This is particularly relevant for extraterrestrial phosphates that may have been exposed to impacts, and we urge the consideration of microstructural data in the interpretation of the primary or secondary nature of elemental abundances and isotopic compositions.

Published

2020

48. Use of EBSD to Identify Primary Magmatic Apatite Inclusions in Zircon

Author

Jack Gillespie, Aaron J Cavosie, Alexander A. Nemchin, and Peter Kinny

Published

2020

49. First zircon evidence of Hadean material in the Ukrainian Shield

Author

Leonid Shumlyanskyy, Simon A. Wilde, Gennadiy Artemenko, Andrey Bekker, Martin J. Whitehouse, and Alexander A. Nemchin

Published

2020

50. Table 1; Figures 1–8. The age of the Sääksjärvi impact structure (Finland): reconciling the timing of small impacts in crystalline basement with that of regional basin development

Author

Kenny, Gavin G., Mänttäri, Irmeli, Schmieder, Martin, Whitehouse, Martin J., Nemchin, Alexander A., Bellucci, Jeremy J., and Merle, Renaud E.

Abstract

Supplementary data: Table 1 and Figures 1–8

Published

2020