Your search keyword '"Lunar meteorite"' showing total 247 results

51. Oldest Immiscible Silica‐rich Melt on the Moon Recorded in a ~4.38 Ga Zircon

Author

Jianzhong Liu, Shijie Li, Yang Li, Xiaojia Zeng, Shijie Wang, Nian Wang, Jialong Hao, Katherine H. Joy, Yangting Lin, and Xiongyao Li

Subjects

Lunar meteorite, Geophysics, Breccia, Geochemistry, General Earth and Planetary Sciences, Geology, Zircon

Abstract

The temporal duration of lunar evolved magmatism is still poorly constrained. In lunar meteorite NWA 10049, a melt inclusion-bearing zircon fragment provides a new tool to understand the composition and age of the melts from which zircon directly crystallized. The studied zircon-hosted melt inclusions are silica-rich and iron-poor (e.g., ~80–90 wt% SiO2

Published

2020

52. RECONSTRUCTING LUNAR METEORITE THERMAL HISTORIES WITH 40AR/39AR THERMOCHRONOLOGY

Author

Simon Mason, John N. Carter, Darren F. Mark, Marissa M. Tremblay, Abigail Robinson, and Peter Chung

Subjects

Thermochronology, Lunar meteorite, Thermal, Geology, Astrobiology

Published

2020

53. Meteorite reconnaissance in Saudi Arabia

Author

Beda A. Hofmann, Sönke Szidat, Mohammed Hakeem, Abdulaziz Al Solami, Siddiq N. Habibullah, A. J. Timothy Jull, Khalid Al Wagdani, Mohammed A. Halawani, Ayman Majoub, Edwin Gnos, and Mahmoud Al Shanti

Subjects

Lunar meteorite, education.field_of_study, 010504 meteorology & atmospheric sciences, Outcrop, Population, Acapulcoite, Geochemistry, Weathering, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Meteorite, Space and Planetary Science, Chondrite, Enstatite, engineering, education, Geology, 0105 earth and related environmental sciences

Abstract

Meteorite searches in Saudi Arabia between 2008 and 2014 yielded 46 meteorites from the Yabrin area (23°N 49°E), 35 meteorites from the Rub’ al-Khali sand desert (19°–20°N, 48°–51°E), and 1 meteorite from Al Haddar. No meteorites were found near Hafar al Batin (29°N 45°E). The 82 new meteorites represent ~57 falls comprising 43 ordinary chondrites, 4 carbonaceous chondrites, 2 enstatite chondrites, 3 ureilites, 3 eucrites, 1 acapulcoite, and 1 lunar meteorite. The median of 31 14C terrestrial ages is 6.2 ka, significantly younger than the Oman population (19.5 ka, n = 128). A further assessment of terrestrial 14C contamination is advised by a 11–15 ka 14C terrestrial age of heavily weathered meteorite Khawr al Fazra 014, geology indicating a terrestrial age >100 ka. Find densities of 0.4–2.8 km-2 for Yabrin and the western Rub’ al-Khali are similar to ~0.5 km-2 observed in Oman. Higher find densities of ~135 km-2 (29 km-2 for masses >10 g) exist on small Pleistocene outcrops in blowouts in the south-central Rub’ al-Khali: 21 unpaired meteorites (four >10 g) were found in 11 blowouts with a combined area of 0.14 km2. The Rub’ al-Khali meteorites show a relatively high degree of weathering (median W 3.6; 2.5 for Yabrin), low median mass (4.3/138 g), and a high H/L ratio (2.3/1.1). The high density of small meteorites is explained by prolonged sand protection and recent deflation. The high meteorite density and relatively high proportion of rare meteorite types render the Rub’ al-Khali blowouts an interesting target for future exploration.

Published

2018

54. Investigation of the source region of the lunar-meteorite group with the remote sensing datasets: Implication for the origin of mare volcanism in Mare Imbrium

Author

Yuko Daket, Masahiro Kayama, Yuzuru Karouji, Naoki Shirai, Nobuyuki Hasebe, Mitsuru Ebihara, M. Ohtake, and Hiroshi Nagaoka

Subjects

Basalt, Lunar meteorite, Meteorite, Impact crater, Meteoroid, Space and Planetary Science, Geochemistry, KREEP, Astronomy and Astrophysics, Ejecta, Geology, Terrane

Abstract

Lunar meteorites provide information about areas of the Moon not sampled by the Apollo and Luna missions, so they can be used as more-representative geochemical datasets for evaluating global lunar evolution. However, the launching craters remain unknown for many lunar meteorites. This paper, therefore, aims to identify the launching sites of lunar meteorites with remote-sensing datasets. This work focuses on one lunar-meteorite group, the Northwest Africa 773 (NWA 773) clan, which has the very-low-Ti basaltic composition and one of the youngest crystallization ages (~3 Ga) among the lunar basaltic meteorites. We investigated the source of the NWA 773 clan by comparing their geochemical compositions and geochronological information with the following remote-sensing datasets: 1) the Lunar Prospector gamma-ray elemental maps (FeO, TiO2, Th) and the SELENE gamma-ray elemental maps (CaO), 2) the surface ages determined from imaging data by using the crater-counting method, and 3) high-spatial-resolution maps of the FeO and TiO2 and spectral-ratio images made from the SELENE multi-band imager data. From these comparisons, the NWA 773 clan is most likely to have originated from the north part of Mare Imbrium inside the Procellarum KREEP Terrane (PKT). Furthermore, the eruption age of surface basalt surrounding the Le Verrier D crater in the north part of Mare Imbrium between 3.0 and 3.3 Ga, and the formation of the Le Verrier D crater, are consistent with the duration of igneous activity and timing of meteoroid impact of the NWA 773 clan. There is a fresh crater with bright ejecta on the edge of the Le Verrier D crater, and it is possibly the young launch crater of this meteorite group.

Published

2021

55. Geochemistry and mineralogy of a feldspathic lunar meteorite (regolith breccia), Northwest Africa 2200.

Author

Nagaoka, Hiroshi, Karouji, Yuzuru, Arai, Tomoko, Ebihara, Mitsuru, and Hasebe, Nobuyuki

Subjects

LUNAR meteorites, GEOCHEMISTRY, MINERALOGY, PETROLOGY, SPHERULES (Geology), ANORTHOSITE

Abstract

Abstract: The lunar meteorite Northwest Africa (NWA) 2200 is a regolith breccia with a ferroan feldspathic bulk composition (Al2O3 = 30.1 wt.%; Mg# = molar 100 × Mg/(Mg + Fe) = 59.2) and low Th content (0.42 μg/g). Lithologically, NWA 2200 is a diverse mixture of lithic and glassy clasts, mineral fragments, and impact glass spherules, all embedded in a dark glassy matrix. NWA 2200 contains some feldspathic brecciated rock components (ferroan anorthositic granulitic breccia, poikiloblastic granulitic breccia, and glassy melt breccia with an intersertal texture). The bulk compositions of these brecciated components indicate they are derived from ferroan troctolitic or noritic anorthosite lithologies (bulk Al2O3 = 26–30 wt.%; bulk FeO/MgO > 1.0). The bulk composition of NWA 2200 is more ferroan and feldspathic than the Apollo feldspathic regolith samples and feldspathic lunar regolith meteorites, and is also more depleted in incompatible elements (e.g., rare earth elements) than Apollo 16 feldspathic regolith samples. We conclude that NWA 2200 originated from a location different to the Apollo landing sites, and may have been sourced from the ferroan KREEP-poor highlands, “KREEP” materials are enriched in such elements as potassium (K), rare earth elements (REE), phosphorus (P). [Copyright &y& Elsevier]

Published

2013

56. Magnetic properties of lunar materials: Meteorites, Luna and Apollo returned samples

Author

Rochette, P., Gattacceca, J., Ivanov, A.V., Nazarov, M.A., and Bezaeva, N.S.

Subjects

*LUNAR meteorites, *MAGNETIC properties, *MAGNETIC susceptibility, *REGOLITH, *PETROLOGY, *BASALT, *MAGNETIZATION, *ANORTHOSITE

Abstract

Abstract: We present the first comprehensive study of the magnetic properties of lunar meteorites and compare them with measurements from Apollo and Luna returned samples. 37 unpaired lunar meteorites were studied, while new susceptibility measurements were performed on 88 Luna soil and rock samples, to complement published Luna and Apollo data. New magnetic data were also obtained on 4 Apollo mare basalt samples. Magnetic susceptibility and saturation remanence appear mainly controlled by the amount of metallic iron added by the regolith-forming processes and meteoritic contamination, as shown by a positive correlation with Ni and Ir content, a decrease with depth in regolith core profiles, and a decrease with increasing soil size fraction. The three sources of lunar materials provide coherent range of magnetic properties, although the much larger abundance of anorthositic highland samples in the meteorite collection allows one to better describe the properties of this major lunar lithology. The observed range of saturation remanence implies that mare basalts cannot contribute significantly to the patchy lunar crustal magnetizations, which must be attributed to superficial impact processed feldspathic or mafic lithologies. [Copyright &y& Elsevier]

Published

2010

57. SIMS Pb/Pb dating of Zr-rich minerals in lunar meteorites Miller Range 05035 and LaPaz Icefield 02224: Implications for the petrogenesis of mare basalt.

Author

Zhang, AiCheng, Hsu, WeiBiao, Li, QiuLi, Liu, Yu, Jiang, Yun, and Tang, GuoQiang

Abstract

Miller Range (MIL) 05035 and LaPaz Icefield (LAP) 02224 are unbrecciated lunar basalt meteorites. In this report, we studied their petrography and mineralogy and made in situ uranogenic Pb/Pb dating of Zr-rich minerals. Petrography and mineralogy of these two lunar meteorites are consistent with previous investigations. The zirconolite Pb/Pb age of MIL 05035 is 3851±8 Ma (2σ), in excellent agreement with previous reports. This age suggests that MIL 05035 could be paired with Asuka 881757, a low-Ti mare basalt meteorite. The magmatic event related to MIL 05035 was probably due to the late heavy impact bombardment on the moon around 3.9 Ga. One baddeleyite grain in LAP 02224 shows a large variation of Pb/Pb age, from 3109±29 to 3547±21 Ma (2σ), much older than the whole-rock age of the same meteorite (∼3.02±0.03 Ga). The other baddeleyite grain in LAP 02224 has an age of 3005±17 Ma (2σ). The result indicates that the minimum crystallization age of LAP 02224 is ∼3.55 Ga and the younger ages could reflect late thermal disturbance on U-Pb system. [ABSTRACT FROM AUTHOR]

Published

2010

58. Uranium–lead systematics of low-Ti basaltic meteorite Dhofar 287A: Affinity to Apollo 15 green glasses

Author

Terada, Kentaro, Sasaki, Yu, Anand, Mahesh, Sano, Yuji, Taylor, Lawrence A., and Horie, Kenji

Subjects

*IGNEOUS rocks, *SPACE flight to the moon, *BASALT, *SEPARATION (Technology)

Abstract

Abstract: Dhofar 287 is a lunar meteorite found in Oman in 2001, which consists of a major portion (95%) of low-Ti mare basalt (Dho 287A) and a minor attached part (∼5%) of regolith breccia (Dho 287B). Here, we report the U–Pb systematics of Dho 287A using data collected with a Sensitive High Resolution Ion Microprobe (SHRIMP). In-situ analyses of five merrillite and three apatite grains, which are resistant to secondary petrologic events, resulted in a total Pb/U isochron age of 3.34±0.20 Ga, in 238U/206Pb–207Pb/206Pb–204Pb/206Pb 3-D space (95% confidence level). The observed Pb–Pb isochron of these eight phosphates coupled with four plagioclase grains also yielded a 207Pb/206Pb age of 3.35±0.13 Ga. This formation age, when considered as the crystallization age of Dho 287A, is similar to crystallization ages of Apollo 15 low-Ti olivine-normative basalts (ONB; 3.3±0.1 Ga). However, the estimated μ-value (238U/204Pb ratio) of Dho 287A is ∼18, which is very different from the reported μ-values of ∼300 for mare basalts from the Apollo collections, including the Apollo 15 ONBs. These μ-values are still significantly lower than those of Apollo KREEP basalt (500 to 1000), although a possible assimilation with KREEP has been previously proposed for Dho 287A using geochemical criteria. Our U–Pb study of Dho 287A, instead, indicates a closer affinity to Apollo 15 green glasses (207Pb/206Pb age of 3.41 Ga with μ-value of 19 to 55), which are considered to be the most primitive products of lunar volcanism. Combining our U–Pb data with the previously reported Sm–Nd systematics (negative ε Nd) of Dho 287A clearly distinguishes this meteorite from those of the Yamato 793169 and Asuka 88175 group which have extremely low μ-value of 10–22, old crystallization ages of 3.9 Ga, and high positive ε Nd, suggesting that Dho 287A may be a representative of an entirely new group of mare basalt derived from previously unsampled source region on the Moon. [Copyright &y& Elsevier]

Published

2008

59. Uranium–lead systematics of phosphates in lunar basaltic regolith breccia, Meteorite Hills 01210

Author

Terada, Kentaro, Sasaki, Yu, Anand, Mahesh, Joy, Katherine H., and Sano, Yuji

Subjects

*IGNEOUS rocks, *ROCKS, *ALBITITE, *ALKALIC igneous rocks

Abstract

Abstract: Chronological studies of brecciated lunar meteorites have proved difficult, because they are mixtures of materials from various sources and the radiometric “clocks” are sometimes affected by the subsequent impact events on the Moon. Here, we report the in-situ U–Pb dating of phosphates in lunar meteorite, Meteorite Hills (MET) 01210, which is a regolith breccia consisting of low-Ti mare basalt clasts and mineral fragments with a minor anorthositic component. In-situ analyses of four merrillite and four apatite grains in MET 01210, which are resistant to secondary events, resulted in a 207Pb/206Pb–204Pb/206Pb isochron age of 3904±85 Ma (95% confidence limit). This phosphate formation age, when considered as the crystallisation age of this low-Ti basalt, is similar to crystallization ages of 3.8–3.9 Ga for unbrecciated low-Ti basalt meteorites, Asuka 881757 and Yamato 793169. This result reinforces the hypothesis that all these three meteorites originated from the same area on the Moon and were launched by a single impact event, consistent with the similarity of launch ages, mineralogical and geochemical signatures. [Copyright &y& Elsevier]

Published

2007

60. Tungsten isotopes and the origin of the Moon

Author

Thorsten Kleine and Thomas S. Kruijer

Subjects

Basalt, Lunar meteorite, Radiogenic nuclide, 010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), Physics::Geophysics, Astrobiology, Geophysics, Magnetic field of the Moon, Lunar magma ocean, Space and Planetary Science, Geochemistry and Petrology, Physics::Space Physics, Origin of the Moon, Earth and Planetary Sciences (miscellaneous), Astrophysics::Earth and Planetary Astrophysics, Formation and evolution of the Solar System, Geology, 0105 earth and related environmental sciences

Abstract

The giant impact model of lunar origin predicts that the Moon mainly consists of impactor material. As a result, the Moon is expected to be isotopically distinct from the Earth, but it is not. To account for this unexpected isotopic similarity of the Earth and Moon, several solutions have been proposed, including (i) post-giant impact Earth–Moon equilibration, (ii) alternative models that make the Moon predominantly out of proto-Earth mantle, and (iii) formation of the Earth and Moon from an isotopically homogeneous disk reservoir. Here we use W isotope systematics of lunar samples to distinguish between these scenarios. We report high-precision 182W data for several low-Ti and high-Ti mare basalts, as well as for Mg-suite sample 77215, and lunar meteorite Kalahari 009, which complement data previously obtained for KREEP-rich samples. In addition, we utilize high-precision Hf isotope and Ta/W ratio measurements to empirically quantify the superimposed effects of secondary neutron capture on measured 182W compositions. Our results demonstrate that there are no resolvable radiogenic 182W variations within the Moon, implying that the Moon differentiated later than 70 Ma after Solar System formation. In addition, we find that samples derived from different lunar sources have indistinguishable 182W excesses, confirming that the Moon is characterized by a small, uniform ∼+26 parts-per-million excess in 182W over the present-day bulk silicate Earth. This 182W excess is most likely caused by disproportional late accretion to the Earth and Moon, and after considering this effect, the pre-late veneer bulk silicate Earth and the Moon have indistinguishable 182W compositions. Mixing calculations demonstrate that this Earth–Moon 182W similarity is an unlikely outcome of the giant impact, which regardless of the amount of impactor material incorporated into the Moon should have generated a significant 182W excess in the Moon. Consequently, our results imply that post-giant impact processes might have modified 182W, leading to the similar 182W compositions of the pre-late veneer Earth's mantle and the Moon.

Published

2017

61. 3.1 Ga crystallization age for magnesian and ferroan gabbro lithologies in the Northwest Africa 773 clan of lunar meteorites

Author

Barry Shaulis, M. Righter, Anthony J. Irving, Thomas J. Lapen, and B. L. Jolliff

Subjects

Basalt, Lunar meteorite, Olivine, 010504 meteorology & atmospheric sciences, Gabbro, Geochemistry, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Baddeleyite, Igneous rock, Geochemistry and Petrology, Breccia, engineering, Petrology, Geology, 0105 earth and related environmental sciences, Zircon

Abstract

The Northwest Africa (NWA) 773 clan of meteorites is a group of paired and/or petrogenetically related stones that contain at least six different lithologies: magnesian gabbro, ferroan gabbro, anorthositic gabbro, olivine phyric basalt, regolith breccia, and polymict breccia. Uranium-lead dates of baddeleyite in the magnesian gabbro, ferroan gabbro, and components within breccia lithologies of paired lunar meteorites NWA 773, NWA 3170, NWA 6950, and NWA 7007 indicate a chronologic link among the meteorites and their components. A total of 50 baddeleyite grains were analyzed and yielded weighted average 207Pb-206Pb dates of 3119.4 ± 9.4 (n = 27), 3108 ± 20 (n = 13), and 3113 ± 15 (n = 10) Ma for the magnesian gabbro, ferroan gabbro, and polymict breccia lithologies, respectively. A weighted average date of 3115.6 ± 6.8 Ma (n = 47/50) was calculated from the baddeleyite dates for all lithologies. A single large zircon grain found in a lithic clast in the polymict breccia of NWA 773 yielded a U-Pb concordia date of 3953 ± 18 Ma, indicating a much more ancient source for some of the components within the breccia. A U-Pb concordia date of apatite and merrillite grains from the magnesian gabbro and polymict breccia lithologies in NWA 773 is 3112 ± 33 Ma, identical to the baddeleyite dates. Magnesian and ferroan gabbros, as well as the dated baddeleyite and Ca-phosphate-bearing detritus in the breccia lithologies, formed during the same igneous event at about 3115 Ma. These data also strengthen proposed petrogenetic connections between magnesian and ferroan gabbro lithologies, which represent some of the youngest igneous rocks known from the Moon.

Published

2017

62. Magnesian anorthosites and a deep crustal rock from the farside crust of the moon

Author

Takeda, Hiroshi, Yamaguchi, A., Bogard, D.D., Karouji, Y., Ebihara, M., Ohtake, M., Saiki, K., and Arai, T.

Subjects

*IGNEOUS rocks, *BRECCIA, *RARE earth metals

Abstract

Abstract: Among over thirty lunar meteorites recovered from the hot deserts and Antarctica, Dhofar 489 is the most depleted in thorium (0.05 ppm), FeO, and rare earth elements (REE). Dhofar 489 is a crystalline matrix anorthositic breccia and includes clasts of magnesian anorthosites and a spinel troctolite. The Mg/(Mg+Fe) mol% (Mg numbers=75–85) of olivine and pyroxene grains in this meteorite are higher than those of the Apollo ferroan anorthosites. Such materials were not recovered by the Apollo and Luna missions. However, remote sensing data suggest that the estimated concentrations of Th and FeO are consistent with the presence of such samples on the farside of the Moon. The differentiation trend deduced from the mineralogy of the anorthositic clasts define a magnesian extension of the ferroan anorthosite (FAN) trend constructed from the Apollo samples. The presence of magnesian anorthositic clasts in Dhofar 489 still offers a possibility that the farside trend with magnesian compositions is more primitive than the FAN trend, and may require a revision of this classical differentiation trend. The Ar–Ar age of Dhofar 489 is 4.23±0.034 Gyr, which is older than most Ar ages reported for highland rocks returned by Apollo. The old Ar–Ar age of impact formation of this breccia and the presence of a fragment of spinel troctolite of deep crustal origin suggest that a basin forming event on the farside excavated the deep crust and magnesian anorthosites before formation of Imbrium. [Copyright &y& Elsevier]

Published

2006

63. Update (2012–2017) on lunar meteorites from Oman

Author

Randy L. Korotev

Subjects

Lunar meteorite, Geophysics, 010504 meteorology & atmospheric sciences, Meteorite, Space and Planetary Science, Geochemistry, Neutron activation analysis, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences

Abstract

This report presents bulk composition data for 10 lunar meteorite stones from Oman for which the names have been approved since June, 2012. On the basis of composition and reported find location, four new meteorites are represented among this group of stones. Data from neutron activation analysis of 371 subsamples of all lunar meteorites from Oman and Saudi Arabia analyzed in this laboratory are presented.

Published

2017

64. Enigmatic cathodoluminescent objects in the Dhofar 025 lunar meteorite: Origin and sources

Author

Franz Brandstätter, K. M. Ryazantsev, Mikhail A. Nazarov, Theodoros Ntaflos, M. O. Anosova, and S. I. Demidova

Subjects

Lunar meteorite, Basalt, Incompatible element, Olivine, 010504 meteorology & atmospheric sciences, Geochemistry, KREEP, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Meteorite, Geochemistry and Petrology, engineering, Plagioclase, Mafic, Geology, 0105 earth and related environmental sciences

Abstract

Dhofar 025 is a lunar highland breccia consisting mainly of anorthositic, with less common noritic, gabbronoritic, and troctolitic material. Rare fragments of low-Ti basalts are present as well, but no KREEP (component enriched in incompatible elements) was found in the meteorite. The cathodoluminescence study of this meteorite showed that its impact–melt matrix contains unusual cathodoluminescent (CL) objects of feldspathic composition, which frequently contain microlites of Fe-Mg spinel (pleonaste). They were presumably formed by impact mixing and melting of olivine and plagioclase with subsequent rapid quenching of the impact melts. Such mixing could happen either during assimilation of anorthosites by picritic/troctolitic magmas or during impact melting of troctolites. The enrichment of CL objects of Dhofar 025 in incompatible trace elements suggests that the mafic component of the impact mixture may be related to the high-magnesium suite rocks, which are frequently enriched in KREEP component. The depletion of CL objects in alkalis indicates their possible relation with residual glasses formed by evaporation. However, the presence of FeO in most objects points to the insignificant extent of evaporation. Thus, evaporation cannot explain the enrichment of the CL objects in Al2O3 and other refractory components, although this process definitely took place in their formation. Their similarity to the lunar pink spinel anorthosites, whose existence was predicted from orbital data, serves as an argument in support of the possible formation of the latters by impact mixing.

Published

2017

65. Donwilhelmsite, IMA 2018-113

Author

Fritz, J., Greshake, A., Klementova, M., Wirth, R., Palatinus, L., Assis Vernandez, V., Böttger, U., and Ferrière, L.

Subjects

lunar Meteorite, Donwilhelmsite, Mineral

Published

2019

66. Investigation of the source region of the lunar-meteorite group with the remote sensing datasets: Implication for the origin of mare volcanism in Mare Imbrium.

Author

Nagaoka, Hiroshi, Ohtake, Makiko, Shirai, Naoki, Karouji, Yuzuru, Kayama, Masahiro, Daket, Yuko, Hasebe, Nobuyuki, and Ebihara, Mitsuru

Subjects

*REMOTE sensing, *TITANIUM dioxide, *LUNAR craters, *METEORITES, *LUNAR maria, *METEORITE craters, *VOLCANISM

Abstract

Lunar meteorites provide information about areas of the Moon not sampled by the Apollo and Luna missions, so they can be used as more-representative geochemical datasets for evaluating global lunar evolution. However, the launching craters remain unknown for many lunar meteorites. This paper, therefore, aims to identify the launching sites of lunar meteorites with remote-sensing datasets. This work focuses on one lunar-meteorite group, the Northwest Africa 773 (NWA 773) clan, which has the very-low-Ti basaltic composition and one of the youngest crystallization ages (~3 Ga) among the lunar basaltic meteorites. We investigated the source of the NWA 773 clan by comparing their geochemical compositions and geochronological information with the following remote-sensing datasets: 1) the Lunar Prospector gamma-ray elemental maps (FeO, TiO 2 , Th) and the SELENE gamma-ray elemental maps (CaO), 2) the surface ages determined from imaging data by using the crater-counting method, and 3) high-spatial-resolution maps of the FeO and TiO 2 and spectral-ratio images made from the SELENE multi-band imager data. From these comparisons, the NWA 773 clan is most likely to have originated from the north part of Mare Imbrium inside the Procellarum KREEP Terrane (PKT). Furthermore, the eruption age of surface basalt surrounding the Le Verrier D crater in the north part of Mare Imbrium between 3.0 and 3.3 Ga, and the formation of the Le Verrier D crater, are consistent with the duration of igneous activity and timing of meteoroid impact of the NWA 773 clan. There is a fresh crater with bright ejecta on the edge of the Le Verrier D crater, and it is possibly the young launch crater of this meteorite group. • The source region of lunar meteorite is investigated with remote sensing datasets. • The basaltic meteorite group, NWA 773 clan originated from Mare Imbrium. • NWA 773 clan likely launched from young crater within the Le Verrier D crater. [ABSTRACT FROM AUTHOR]

Published

2021

67. Visible and near-infrared spectral survey of lunar meteorites recovered by the National Institute of Polar Research

Author

Sho Sasaki, H. Kojima, A. Yamaguchi, K. Uemoto, Takahiro Hiroi, Tomoko Arai, H. Kaiden, and Makiko Ohtake

Subjects

Lunar meteorite, 010504 meteorology & atmospheric sciences, Ecology, Spectrometer, Operations research, Near-infrared spectroscopy, Mineralogy, Pyroxene, Reflectance, Aquatic Science, 010502 geochemistry & geophysics, 01 natural sciences, Spectral line, Meteorite, Clastic rock, General Earth and Planetary Sciences, Exploration, Spectroscopy, Ecology, Evolution, Behavior and Systematics, Geology, Lunar, 0105 earth and related environmental sciences

Abstract

Accepted: 2016-06-07, 資料番号: SA1160169000

Published

2016

68. Reported sulfate mineral in lunar meteorite <scp>PCA</scp> 02007 is impact glass

Author

Juliane Gross, Allan H. Treiman, and George E. Harlow

Subjects

Lunar meteorite, Mineral, 010504 meteorology & atmospheric sciences, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Astrobiology, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Sulfate, Geology, 0105 earth and related environmental sciences

Published

2016

69. Petrology and geochemistry of feldspathic impact-melt breccia Abar al' Uj 012, the first lunar meteorite from Saudi Arabia

Author

Pierre Lanari, Siddiq N. Habibullah, A. J. Timothy Jull, Randy L. Korotev, Marianna Mészáros, Edwin Gnos, Khalid Al-Wagdani, Ayman Mahjoub, Abdulaziz A. Al-Solami, Nicolas D. Greber, Ingo Leya, Beda A. Hofmann, and Richard C. Greenwood

Subjects

Lunar meteorite, Basalt, 010504 meteorology & atmospheric sciences, Geochemistry, KREEP, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Meteorite, 13. Climate action, Space and Planetary Science, Clastic rock, Pigeonite, Breccia, engineering, Plagioclase, Petrology, Geology, 0105 earth and related environmental sciences

Abstract

Abar al' Uj (AaU) 012 is a clast-rich, vesicular impact-melt (IM) breccia, composed of lithic and mineral clasts set in a very fine-grained and well-crystallized matrix. It is a typical feldspathic lunar meteorite, most likely originating from the lunar farside. Bulk composition (31.0 wt% Al2O3, 3.85wt% FeO) is close to the mean of feldspathic lunar meteorites and Apollo FAN-suite rocks. The low concentration of incompatible trace elements (0.39ppmTh, 0.13ppm U) reflects the absence of a significant KREEP component. Plagioclase is highly anorthitic with a mean of An(96.9)Ab(3.0)Or(0.1). Bulk rock Mg# is 63 and molar FeO/MnO is 76. The terrestrial age of the meteorite is 33.4 +/- 5.2kyr. AaU 012 contains a similar to 1.4x1.5mm(2) exotic clast different from the lithic clast population which is dominated by clasts of anorthosite breccias. Bulk composition and presence of relatively large vesicles indicate that the clast was most probably formed by an impact into a precursor having nonmare igneous origin most likely related to the rare alkali-suite rocks. The IM clast is mainly composed of clinopyroxenes, contains a significant amount of cristobalite (9.0 vol%), and has a microcrystalline mesostasis. Although the clast shows similarities in texture and modal mineral abundances with some Apollo pigeonite basalts, it has lower FeO and higher SiO2 than any mare basalt. It also has higher FeO and lower Al2O3 than rocks from the FAN- or Mg-suite. Its lower Mg# (59) compared to Mg-suite rocks also excludes a relationship with these types of lunar material.

Published

2016

70. Shock Metamorphism of Plagioclase-maskelynite in the Lunar Meteorite Mount DeWitt 12007

Author

Hyun Na Kim and Changkun Park

Subjects

Lunar meteorite, Shock metamorphism, 010504 meteorology & atmospheric sciences, engineering, Geochemistry, Plagioclase, Maskelynite, Geophysics, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences

Published

2016

71. Thermal and irradiation history of lunar meteorite Dhofar 280

Author

Ulrich Ott, A. I. Buikin, Ekaterina V. Korochantseva, Jens Hopp, A. V. Korochantsev, Mario Trieloff, and C. A. Lorenz

Subjects

Lunar meteorite, Geophysics, 010504 meteorology & atmospheric sciences, Space and Planetary Science, Thermal, Irradiation, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Astrobiology

Published

2016

72. NanoSIMS imaging method of zircon U-Pb dating

Author

Weifan Xing, Wei Yang, Jianchao Zhang, Sen Hu, Wei-RZ Wang, Jialong Hao, and Yangting Lin

Subjects

Lunar meteorite, 010504 meteorology & atmospheric sciences, Meteorite, Metamorphic rock, Breccia, Geochemistry, General Earth and Planetary Sciences, Mineralogy, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Zircon

Abstract

We report an imaging method of zircon U-Pb dating with NanoSIMS 50L, which overcomes the significant U-Pb fractionation as the pit was sputtered deeper during conventional spot mode analysis and can be applied to irregular small grains or heterogeneous areas of zircon. The U-Pb and Pb-Pb ages can be acquired simultaneously for 2 μm×2 μm (for small grains) or 1 μm×9 μm (for zoned grains), together with Zr, Y and other trace elements distributions. Using zircon M257 as standard, the U-Pb ages of other zircon standards, including Qinghu, Plesovice, Temora and 91500, were measured to (2σ) as 158.8±0.8, 335.9±3.4, 412.0±12 and 1067±12 Ma, respectively, consistent with the recommended values within the analytical uncertainties. Tiny zircon grains in the impact melt breccia of the lunar meteorite SaU 169 were also measured in this study, with a Pb-Pb age of 3912±14 Ma and a U-Pb age of 3917±17 Ma, similar to previous results reported for the same meteorite. The imaging method was also applied to determine U-Pb age of the thin overgrowth rims of Longtan metamorphic zircon, with a Pb-Pb age of 1933±27 Ma and a U-Pb age of 1935±25 Ma, clearly distinct from the Pb-Pb age of 2098±61 Ma and the U-Pb age of 2054±40 Ma for detrital cores.

Published

2016

73. Phosphate ages in Apollo 14 breccias: Resolving multiple impact events with high precision U–Pb SIMS analyses

Author

F. Thiessen, Joshua F. Snape, Jeremy J. Bellucci, Marion Grange, Martin J. Whitehouse, Alexander A. Nemchin, Chemistry, and Analytical, Environmental & Geo-Chemistry

Subjects

Lunar meteorite, Systematic difference, 010504 meteorology & atmospheric sciences, biology, Apollo, Geochemistry, Mineralogy, Geology, U-Pb, 010502 geochemistry & geophysics, biology.organism_classification, 01 natural sciences, Apatite, Phosphates, Apollo 14, Geochemistry and Petrology, meteorite impacts, visual_art, Breccia, visual_art.visual_art_medium, Geologi, SIMS, Lunar, 0105 earth and related environmental sciences

Abstract

The U–Pb systems of apatite and merrillite grains within four separate Apollo 14 impact melt breccia samples were analysed by secondary ion mass spectrometry. No systematic difference was identified between the 207 Pb/ 206 Pb ages of the apatites and merrillites. A combined 207 Pb/ 206 Pb age of 3927 ± 2 Ma (95% conf.) is determined for three of these samples (14305,103: 3926 ± 4 Ma; 14306,150: 3926 ± 6 Ma; 14314,13: 3929 ± 4 Ma). By combining these data with the ages previously obtained for zircons in Apollo 12 impact melt breccia fragments and the lunar meteorite SaU 169, a weighted average age of 3926 ± 2 Ma (95% conf.) is obtained, which is attributed to the formation of the Imbrium basin. An age of 3943 ± 5 Ma is determined for the fourth breccia (14321,134), which is similar to ages of 3946 ± 15 Ma and 3958 ± 19 Ma, obtained from several older phosphates in 14305,103 and 14314,13. The weighted average of these three older ages is 3944 ± 4 Ma (95% conf.). This is indistinguishable to the age (3938 ± 4 Ma; 2 σ ) obtained for a different Apollo 14 impact melt breccia in a previous study. After investigating likely sources for this older ∼3940 Ma age, we conclude that the Humorum or Serenitatis basin forming events are likely candidates. The potential identification of two large impact events within ∼15 Myrs has important implications for the rate of lunar bombardment around 3.95–3.92 Ga. This study demonstrates the importance of high-precision age determinations for interpreting the impact record of the Moon, as documented in lunar samples.

Published

2016

74. Petrography and Shock Metamorphism of the Lunar Breccia Meteorite NWA 13120.

Author

Xia, Zhipeng, Miao, Bingkui, Zhang, Chuantong, Chen, Hongyi, Xie, Lanfang, Ranjith, P. M., Zhang, Yikai, and Si, Bowen

Subjects

*METEORITES, *PETROLOGY, *BRECCIA, *LUNAR soil, *IMPACT of asteroids with Earth, *LUNAR surface, *PLAGIOCLASE

Abstract

Lunar meteorites are the fragments of rocks that fell on Earth because of the impacts of asteroids on the Moon. Such rocks preserve information about the composition, evolutionary process, and shock history of the lunar surface. NWA 13120 is a recently discovered lunar breccia meteorite having features of strong shock, which is composed of lithic and mineral clasts in a matrix of very fine-grained (<10 μm) and recrystallized olivine-plagioclase with a poikilitic-like texture. As the most abundant lithic clasts, the crystalline impact melt (CIM) clasts can be divided into four types according to their texture and mineral composition: (1) anorthosites or troctolitic anorthosite with a poikilitic-like texture, but the mineral content is different from that of the matrix; (2) anorthosites containing basaltic fragments and rich in vesicles; (3) troctolitic anorthosite containing metamorphic olivine mineral fragments; (4) troctolitic anorthosite containing troctolite fragments. Based on the petrology and mineralogy, NWA 13120 is a lunar meteorite that was derived from the ferrous anorthosite suite (FANs) of the lunar highlands, while its texture suggests it is a crystalline impact melt breccia. In addition, we infer that the parent rock of NWA 13120 is a lunar regolith breccia enriched in glass fragments. During the shock process, at pressures of more than 20 GPa, all plagioclase fragments were transformed into maskelynites, and olivine fragments occurred metamorphism. The post-shock temperature led to the partial melting of the basaltic fragments. Subsequently, all glass with diverse components in the parent rock were devitrified and recrystallized, forming the common olivine-plagioclase poikilitic-like texture and different CIM clasts. Meanwhile, the devitrification of maskelynite formed the accumulation of a large number of plagioclase microcrystals. Therefore, NWA 13120 is a meteorite of great significance for understanding the local shock metamorphism of lunar rocks on the lunar surface. [ABSTRACT FROM AUTHOR]

Published

2021

75. Mineral chemistry and in situ U Pb geochronology of the mare basalt Northwest Africa 10597: Implications for low-Ti mare volcanism around 3.0 Ga

Author

Yunhua Wu and Weibiao Hsu

Subjects

Lunar meteorite, Basalt, Olivine, Tranquillityite, 010504 meteorology & atmospheric sciences, Geochemistry, Astronomy and Astrophysics, Pyroxene, engineering.material, 01 natural sciences, Baddeleyite, Shock metamorphism, Space and Planetary Science, 0103 physical sciences, engineering, Plagioclase, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Unbrecciated mare basalts are rare in the lunar meteorite collection. Found in 2015, Northwest Africa (NWA) 10597 is a medium-grained low-Ti mare basalt with a subophitic texture. The meteorite consists mostly of mm-sized pyroxene and plagioclase, with minor olivine, spinel, ilmenite, phosphates, silica, and trace Zr-rich minerals, such as baddeleyite, zirconolite and tranquillityite. A portion of plagioclase and silica has been transformed to their high-pressure polymorphs due to shock metamorphism. NWA 10597 has a low TiO2 content (2.9 wt%) but is relatively enriched in rare earth elements (REE) (Laaverage = 65 × CI) with an overall unfractionated pattern except for a negative Eu anomaly. Calculated REE concentrations of parent melts in equilibrium with Mg-rich pyroxene and Ca-rich plagioclase suggest no significant assimilation of REE-rich melts after the onset of pyroxene crystallization. In situ U Pb analyses of baddeleyite and apatite reveal a mutually consistent age of ~3.0 Ga, which is also in excellent agreement with that of low-Ti mare basalts NWA 4734 and LaPaz Icefield (LAP) 02205 dated with other independent techniques. The concordance suggests no significant thermal disturbance in the U Pb isotopic system of NWA 10597 although it was heavily shocked. NWA 10597 closely resembles NWA 4734 in terms of petrographic texture, mineral chemistry and geochronology, indicating a pairing relationship.

Published

2020

76. Apollo 12 breccia 12013: Impact-induced partial Pb loss in zircon and its implications for lunar geochronology

Author

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

Subjects

Lunar meteorite, Felsite, 010504 meteorology & atmospheric sciences, U-Pb dating, Geochemistry, engineering.material, zircon, 010502 geochemistry & geophysics, 01 natural sciences, Igneous rock, Apollo 12, Lithic fragment, Geochemistry and Petrology, Geochronology, Breccia, engineering, Plagioclase, Moon, Pb loss, Geology, 0105 earth and related environmental sciences, Zircon, breccia

Abstract

Apollo 12 breccia 12013 is composed of two portions, one grey in colour, the other black. The grey portion of the breccia consists mainly of felsite thought to have formed during a single crystallisation event, while the black part is characterized by presence of lithic fragments of noritic rocks and individual plagioclase crystals. In this study, U-Pb analyses of Ca-phosphate and zircon grains were conducted in both portions of the breccia. The zircon grains within the grey portion yielded a large range of ages (4154 ± 7 to 4308 ± 6 Ma, 2σ) and show decreasing U and Th concentrations within the younger grains. Moreover, some grains exhibit recrystallisation features and potentially formation of neoblasts. The latter process requires high temperatures above 1600–1700 °C leading to the decomposition of the primary zircon grain and subsequent formation of new zircon occurring as neoblasts. As a result of the high temperatures, the U-Pb system of the remaining original zircon grains was most likely open for Pb diffusion causing partial resetting and the observed range of 207Pb/206Pb ages. The event that led to the Pb loss in zircon could potentially be dated by the U-Pb system in Ca-phosphates, which have a weighted average 207Pb/206Pb age across both lithologies of 3924 ± 3 Ma (95% conf.). This age is identical within error to the combined average 207Pb/206Pb age of 3926 ± 2 Ma that was previously obtained from Ca-phosphates within Apollo 14 breccias, zircon grains in Apollo 12 impact melt breccias, and the lunar meteorite SaU 169. This age was interpreted to date the Imbrium impact. The zircon grains located within the black portion of the breccia yielded a similar range of ages (4123 ± 13 to 4328 ± 14 Ma, 2σ) to those in the grey portion. Given the brecciated nature of this part of the sample, the interpretation of these ages as representing igneous crystallisation or resetting by impact events remains ambiguous since there is no direct link to their source rocks via textural relationships or crystal chemistry. Similarly, the currently available zircon data set for all lunar samples may be distorted by partial Pb loss, resulting in meaningless and misleading age distribution patterns. Therefore, it is crucial to fully understand and recognize the processes and conditions that may lead to partial resetting of the U-Pb system in zircon in order to better constrain the magmatic and impact history of the Moon.

Published

2018

77. SEM-based Quantitative Analysis of Lunar Meteorite Northwest Africa 2727

Author

Stephen M. Seddio and Sarah N. Valencia

Subjects

Lunar meteorite, Quantitative analysis (finance), Geochemistry, Instrumentation, Geology

Published

2019

78. Lunar meteorite Yamato-983885: Noble gases, nitrogen and cosmic ray exposure history

Author

R. R. Mahajan

Subjects

Lunar meteorite, Basalt, Materials science, chemistry.chemical_element, Astronomy and Astrophysics, Cosmic ray, Nitrogen, Regolith, Astrobiology, chemistry, Meteorite, Space and Planetary Science, Breccia, Norite

Abstract

Noble gases and nitrogen have been in lunar meteorite from antartcica: the polymict regolith breccias, Yamato-983885 (hereafter Y-983885). Y-983885 has highest concentration of trapped noble gases (Ar, Kr, and Xe) among all the lunar meteorites and returned lunar samples. Noble gases and nitrogen abundances measured in two samples of the lunar meteorite Y-983885. The concentration of trapped noble gases in Y-983885 (A) are, 20Ne=3.69×10−3, 36Ar=12.6×10−4, 84kr=8.57×10−7 and 132Xe=1.63×10−7 ccSTP/g. The cosmic-ray exposure ages for Y-983885 are thus calculated to be T21 (A)=1592±232 Ma and T21 (B)=574±85 Ma for 2π geometry (using production rates as per Hohenberg et al., 1978 and bulk composition ). The exposure ages of samples A and B differ, indicating that they have undergone different exposure scenarios on the lunar surface. The different irradiation ages (T21 (A)=1592±232 Ma and T21 (B)=574±85 Ma) indicates that the regolith material which constitutes the meteorite Y-983885 resided at different shielding depths on lunar surface before agglomeration into the final meteorite. Exposure ages calculated using end member compositon like norite, basalt, tractolite (1947 to 1365 and 711 to 455 for A and B respectively) indicates clearly that the two samples A and B has undergone different exposure on Moon. The 20Ne/22Ne ratio of 13.60±0.01 in temperature step 400 °C of Y-983885 (A) demonstrate a clear retention of solar wind signature in this meteorite. The presence of high contents of trapped solar wind gases indicates that Y-983885 consists of mature lunar regolith material. Variable amounts of solar gases as well as cosmogenic noble gases indicate that Y-983885 (A and B) is compacted from several fragments that were exposed at the surface and/or at various depths in the regolith, before becoming part of Y-983885.

Published

2015

79. A rock fragment related to the magnesian suite in lunar meteorite Allan Hills (ALHA) 81005

Author

Allan H. Treiman and Juliane Gross

Subjects

Lunar meteorite, Basalt, Geophysics, Meteorite, Geology of the Moon, Geochemistry and Petrology, Chondrite, Geochemistry, Phenocryst, KREEP, Mineralogy, Geology, Troilite

Abstract

Among the lunar samples that were returned by the Apollo missions are many cumulate plutonic rocks with high Mg# [molar Mg/(Mg+Fe) in %] and abundances of KREEP elements (potassium, rare earth elements, phosphorus, U, Th, etc.) that imply KREEP-rich parental magmas. These rocks, collectively called the magnesian suite, are nearly absent from sampling sites distant from Imbrium basin ejecta, including those of lunar highlands meteorites. This absence has significant implications for the early differentiation of the Moon and its distribution of heat-producing elements (K, Th, U). Here, we analyze a unique fragment of basalt with the mineralogy and mineral chemistry of a magnesian suite rock, in the lunar highlands meteorite Allan Hills (ALH) A81005. In thin section, the fragment is 700 × 300 μm, and has a sub-ophitic texture with olivine phenocrysts, euhedral plagioclase grains (An97-70),and interstitial pyroxenes. Its minerals are chemically equilibrated. Olivine has Fe/Mn ~ 70 (consistent with a lunar origin), and Mg# ~80, which is consistent with rocks of the magnesian suite and far higher than in mare basalts. It has a rich suite of minor minerals: fluorapatite, ilmenite, Zr-armalcolite, chromite, troilite, silica, and Fe metal (Ni = 3.8%, Co = 0.17%). The metal is comparable to that in chondrite meteorites, which suggests that the fragment is from an impact melt. The fragment itself is not a piece of magnesian suite rock (which are plutonic), but its mineralogy and mineral chemistry suggest that its protolith (which was melted by impact) was related to the magnesian suite. However, the fragment’s mineral chemistry and minor minerals are not identical to those of known magnesian suite rocks, suggesting that the suite may be more varied than apparent in the Apollo samples. Although ALHA81005 is from the lunar highlands (and likely from the farside), Clast U need not have formed in the highlands. It could have formed in an impact melt pool on the nearside and been transported by meteoroid impact. Lunar highlands meteorites should be searched for rock fragments related to the magnesian-suite rocks, but the fragments are rare and may have mineral compositions similar to some meteoritic (impactor) materials.

Published

2015

80. Constraining the source regions of lunar meteorites using orbital geochemical data

Author

Tom Nordheim, Katherine H. Joy, Ian A. Crawford, and Abigail Calzada-Diaz

Subjects

Lunar meteorite, Basalt, Gamma ray spectrometer, Regolith, Astrobiology, Lunar meteorites, Lunar Prospector, Lunar Chemistry, es, Geophysics, Meteorite, Space and Planetary Science, Breccia, cps, Potential source, Achondrite, Geology

Abstract

Lunar meteorites provide important new samples of the Moon remote from regions visited by the Apollo and Luna sample return missions. Petrologic and geochemical analysis of these meteorites, combined with orbital remote sensing measurements, have enabled additional discoveries about the composition and age of the lunar surface on a global scale. However, the interpretation of these samples is limited by the fact that we do not know the source region of any individual lunar meteorite. Here, we investigate the link between meteorite and source region on the Moon using the Lunar Prospector gamma ray spectrometer remote sensing data set for the elements Fe, Ti, and Th. The approach has been validated using Apollo and Luna bulk regolith samples, and we have applied it to 48 meteorites excluding paired stones. Our approach is able broadly to differentiate the best compositional matches as potential regions of origin for the various classes of lunar meteorites. Basaltic and intermediate Fe regolith breccia meteorites are found to have the best constrained potential launch sites, with some impact breccias and pristine mare basalts also having reasonably well-defined potential source regions. Launch areas for highland feldspathic meteorites are much less well constrained and the addition of another element, such as Mg, will probably be required to identify potential source regions for these.

Published

2015

81. Mineralogy and petrology of lunar meteorite Northwest Africa 2977 consisting of olivine cumulate gabbro including inverted pigeonite

Author

Nagaoka, Hiroshi, Karouji, Yuzuru, Takeda, Hiroshi, Fagan, Timothy J., Ebihara, Mitsuru, and Hasebe, Nobuyuki

Published

2015

82. H and Cl isotope systematics of apatite in brecciated lunar meteorites Northwest Africa 4472, Northwest Africa 773, Sayh al Uhaymir 169, and Kalahari 009

Author

Romain Tartèse, Ian A. Franchi, Mahesh Anand, and Katherine H. Joy

Subjects

Basalt, Lunar meteorite, Geochemistry, Mineralogy, Hydroxylapatite, Apatite, Silicate, chemistry.chemical_compound, Geophysics, chemistry, Meteorite, Space and Planetary Science, Chondrite, Clastic rock, visual_art, visual_art.visual_art_medium, Geology

Abstract

We have investigated the H and Cl systematics in apatite from four brecciated lunar meteorites. In Northwest Africa (NWA) 4472, most of the apatites contain ∼2000–6000 ppm H2O with δD between −200 and 0‰, except for one grain isolated in the matrix, which contains ∼6000 ppm H2O with δD of ∼500–900‰. This low-δD apatite contains ∼2500–7500 ppm Cl associated with δ37 Cl of ∼15–20‰, while the high-δD grain contains ∼2500 ppm Cl with δ37 Cl of ∼7–15‰. In NWA 773, apatites in a first group contain ∼700–2500 ppm H2O with δD values averaging around ∼0 ± 100‰, while apatites in a second group contain ∼5500–16500 ppm H2 O with δD ∼250 ± 50‰. In Sayh al Uhaymir (SaU) 169 and Kalahari (Kal) 009, apatites are similar in terms of their H2O contents (∼600–3000 ppm) and δD values (−100 to 200‰). In SaU 169, apatites contain ∼6000–10,000 ppm Cl, characterized by δ37 Cl of ∼5–12‰. Overall, most of the analyzed apatite grains have δD within the range reported for carbonaceous chondrites, similar to apatite analyzed in ancient (>3.9 Ga) lunar magmatic. One grain in NWA 4472 has H and Cl isotope compositions similar to apatite from mare basalts. With an age of 4.35 Ga, this grain could be a representative of the oldest known lunar volcanic activity. Finally, since numerous evolved clasts in NWA 773 formed through silicate liquid immiscibility, the apatite grains with extremely high H2 O contents, reaching pure hydroxylapatite composition, could provide insights into the effects of such process on the evolution of volatiles in lunar magmas.

Published

2014

83. The petrogenesis of impact basin melt rocks in lunar meteorite Shi r 161

Author

Anthony J. Irving, Thomas J. Lapen, Bradley L. Jolliff, Axel Wittmann, and Randy L. Korotev

Subjects

Lunar meteorite, Petrography, Incompatible element, Geophysics, Meteorite, Impact crater, Geochemistry and Petrology, Breccia, Geochemistry, Regolith, Geology, Petrogenesis

Abstract

This study explores the petrogenesis of Shisr 161, an immature lunar regolith breccia meteorite with low abundances of incompatible elements, a feldspathic affinity, and a significant magnesian component. Our approach was to identify all clasts >0.5 mm in size in a thin section, characterize their mineral and melt components, and reconstruct their bulk major and minor element compositions. Trace element concentrations in representative clasts of different textural and compositional types indicate that the clast inventory of Shisr 161 is dominated by impact melts that include slowly cooled cumulate melt rocks with mafic magnesian mineral assemblages. Minor exotic components are incompatible-element-rich melt spherules and glass fragments, and a gas-associated spheroidal precipitate. Our hypothesis for the petrologic setting of Shisr 161 is that the crystallized melt clasts originate from the upper ~1 km of the melt sheet of a 300 to 500 km diameter lunar impact basin in the Moon’s feldspathic highlands. This hypothesis is based on size requirements for cumulate impact melts and the incorporation of magnesian components that we interpret to be mantle-derived. The glassy melts likely formed during the excavation of the melt sheet assemblage, by an impact that produced a >15 km diameter crater. The assembly of Shisr 161 occurred in a proximal ejecta deposit of this excavation event. A later impact into this ejecta deposit then launched Shisr 161 from the Moon. Our geochemical modeling of remote sensing data combined with the petrographic and chemical characterization of Shisr 161 reveals a preferred provenance on the Moon’s surface that is close to pre-Nectarian Riemann-Fabry basin.

Published

2014

84. Case study of magmatic differentiation trends on the Moon based on lunar meteorite Northwest Africa 773 and comparison with Apollo 15 quartz monzodiorite

Author

Akiko Suginohara, Timothy J. Fagan, Yuki Wakabayashi, and Daiju Kashima

Subjects

Basalt, Lunar meteorite, Fractional crystallization (geology), Olivine, Gabbro, Geochemistry, Mineralogy, KREEP, Pyroxene, engineering.material, Geochemistry and Petrology, engineering, Igneous differentiation, Geology

Abstract

Pyroxene and feldspar compositions indicate that most clasts from the Northwest Africa 773 (NWA 773) lunar meteorite breccia crystallized from a common very low-Ti (VLT) mare basalt parental magma on the Moon. An olivine cumulate (OC), with low-Ca and high-Ca pyroxenes and plagioclase feldspar formed during early stages of crystallization, followed by pyroxene gabbro, which is characterized by zoned pyroxene (Fe# = molar Fe/(Fe + Mg) × 100 from ∼35 to 90; Ti# = molar Ti/(Ti + Cr) × 100 from ∼20 to 99) and feldspar (∼An90–95Ab05–10 to An80–85Ab10–16). Late stage lithologies include alkali-poor symplectite consisting of fayalite, hedenbergitic pyroxene and silica, and alkaline-phase-ferroan clasts characterized by K-rich glass and/or K,Ba-feldspar with fayalite and/or pyroxene. Igneous silica only occurs with the alkaline-phase-ferroan clasts. This sequence of clasts represents stages of magmatic evolution along a ferroan–titanian trend characterized by correlated Fe# and Ti# in pyroxene, and a wide range of increase in Fe# and Ti# prior to crystallization of igneous silica. Clasts of Apollo 15 quartz monzodiorite (QMD) also have pyroxene co-existing with silica, but the QMD pyroxene has more moderate Fe# (∼70). Thus, in AFM components (A = Na2O + K2O, M = MgO, F = FeO), the QMD clasts are similar to the terrestrial calc-alkaline trend (silica-enrichment at moderate Fe#), whereas the ferroan–titanian trend is similar to the terrestrial tholeiitic trend (silica-enrichment only after strong increase in Fe#). However, the variations in SiO2-contents of QMD clasts are due to variable mixing of SiO2-rich and FeO-rich immiscible liquids (i.e., not a progressive increase in SiO2). Immiscibility occurred after fractionation of a KREEP-rich parent liquid. A third trend is based on zoning relations within the NWA 773 OC, where pyroxene Ti# increases at constant Fe# with proximity to intercumulus, incompatible element-rich pockets rich in K,Ba-feldspar and Ca-phosphates. This type of fractionation (increasing refractory trace elements at constant Fe#) in a cumulate parent rock may have been important for generating lunar rocks that combine low Fe# with high incompatible trace element concentrations, such as KREEP basalts and the magnesian suite. MELTS ( Ghiorso and Sack, 1995 , Asimow and Ghiorso, 1998 ) models of one VLT, one low-Ti and two high-Ti mare basalts and one KREEP basalt all show evolution from low to high Fe# residual liquids during fractional crystallization; however strong enrichments in FeO-concentrations are limited to the VLT and low-Ti liquids. In the high-Ti liquids, crystallization of Fe–Ti-oxides prevents enrichment in FeO, and the increases in Fe# are due to depletion of MgO. Fe–Ti-oxide fractionation results in steady silica-enrichment in the high-Ti mare compositions. Intervals of FeO-enrichment on the VLT and low-Ti mare liquid lines of descent are linked to shifts from olivine to pyroxene crystallization. The onset of plagioclase feldspar crystallization limits the depletion of FeO during crystallization of one high-Ti mare basalt and of the KREEP basalt composition modeled.

Published

2014

85. Lunar meteorite, Dhofar 1428: Feldspathic breccia containing KREEP and meteoritic components

Author

Mitsuru Ebihara, Yoshihiro Hidaka, and Akira Yamaguchi

Subjects

Lunar meteorite, Geophysics, Mineral, Meteorite, Space and Planetary Science, Chondrite, Breccia, Geochemistry, KREEP, Platinum group, Regolith, Geology

Abstract

We have studied the feldspathic lunar meteorite Dhofar 1428 chemically and petrologically to better understand the evolution of the lunar surface. Dhofar 1428 is a feldspathic regolith breccia derived from the lunar highland. Bulk chemical and mineral compositions of Dhofar 1428 are similar to those of other feldspathic lunar meteorites. We found a few clasts of evolved lithologies, such as K-rich plagioclases and quartz monzogabbro. Dhofar 1428 contains approximately 1 wt% of chondritic materials like CM chondrite on the basis of abundances of platinum group elements (Ru, Rh, Pd, Os, Ir, and Pt).

Published

2014

86. Apatites in lunar KREEP basalts: The missing link to understanding the H isotope systematics of the Moon

Author

Francis M. McCubbin, Mahesh Anand, Charles K. Shearer, Ian A. Franchi, Romain Tartèse, and Stephen M. Elardo

Subjects

Lunar meteorite, Basalt, Isotope fractionation, Geology of the Moon, Lunar magma ocean, Geochemistry, Pyroclastic rock, KREEP, Geology, Mantle (geology)

Abstract

Recent re-analyses of lunar samples have undoubtedly measured indigenous water, challenging the paradigm of a “dry” Moon, and arguing that some portions of the lunar interior are as wet as some regions of the Earth’s mantle and that water in both planetary bodies likely share a common origin. Mare basalts indirectly sample the lunar mantle and are affected by petrogenetic processes such as crystallization and degassing that can modify characteristics of indigenous water in primary mantle melts. Analyses of apatite in phosphorus-rich KREEP (K + REE [rare earth elements] + P) basalts may provide more reliable estimates for the water content of lunar magmas, as some apatites likely crystallized before substantial degassing occurred. In lunar KREEP basalt sample 15386, apatite H 2 O content and H isotopic composition suggest that degassing occurred during apatite crystallization, the lowest δD value of 90‰ ± 100‰ representing an upper limit for the isotopic composition of water in the parental magma. Interpretation of the data for KREEP basalt 15386 suggests that this basalt is characterized by relatively elevated H 2 O contents and CI chondrite–type δD values, similar to those proposed for other mare basalts and pyroclastic glasses. On the other hand, most of the apatites in lunar KREEP basalt 72275 and lunar meteorite NWA 773 crystallized before degassing and H isotope fractionation, and their D/H ratios thus directly refl ect those of their source regions. These apatites have an average δD value of –130‰ ± 50‰, suggesting the presence of a water reservoir in the Moon characterized by moderate H 2 O contents and H isotopic composition similar to that of Earth’s interior. These fi ndings imply that signifi cant amounts of water in the Moon were inherited from the proto-Earth, surviving the purported Moon-forming impact event.

Published

2014

87. Magma chamber dynamics recorded by oscillatory zoning in pyroxene and olivine phenocrysts in basaltic lunar meteorite Northwest Africa 032

Author

Charles K. Shearer and Stephen M. Elardo

Subjects

Lunar meteorite, Olivine, Mineralogy, Pyroxene, Magma chamber, engineering.material, Geophysics, Augite, Geochemistry and Petrology, Magma, Pigeonite, engineering, Phenocryst, Geology

Abstract

Oscillatory zoning in silicate minerals, especially plagioclase, is a common feature found in volcanic rocks from various terrestrial tectonic settings, but is nearly absent in the lunar environment. Here we report backscattered electron images, quantitative wavelength-dispersive spectrometry (WDS) analyses, and qualitative WDS elemental X-ray maps that reveal oscillatory zoning of Mg, Ca, Fe, Ti, Al, Cr, and Mn in euhedral pyroxene phenocrysts, and faint oscillatory zoning of P in olivine phenocrysts in basaltic lunar meteorite Northwest Africa (NWA) 032. This is only the third known occurrence of oscillatory zoning in lunar silicate minerals. Zoning bands in pyroxene range from ~3–5 μm up to ~60 μm in width, but are typically ~10–20 μm in width. Oscillatory bands are variable in width over short distances, often within a single grain. Most oscillatory bands preserve a euhedral form and have sharp edges; however some bands have jagged or uneven edges indicative of resorption surfaces. The short-scale oscillatory nature of the zoning in pyroxene is overprinted on longer-scale core to rim normal magmatic zoning from pigeonite to augite compositions. Oscillatory zoning of P in olivine is faint and only resolvable with high beam current (400 nA) mapping. Bands of higher P are typically only a few micrometers in width, and although they preserve a euhedral form, they are not traceable around the full circumference of a grain and have variable spacing. Resorption surfaces, longer-scale normal magmatic zoning, and relatively thick oscillatory bands are indicative of the formation of these chemical oscillations as a result of variable magma composition. Pyroxenes likely experienced variable liquid compositions as a result of convection in a differentially cooling, chemically stratified magma chamber. Periodic replenishments of progressively decreasing volumes of primitive parental magma are also permissible and may have enabled convection. In a convection model, Mg-rich bands reflect growth in the lower, warmer, more crystal-poor regions of the chamber, whereas Ca-Al-Ti-Cr-rich bands reflect growth in the upper, cooler, more crystal-rich regions of the chamber. The limited duration of crystallization in the magma chamber and the slow diffusion rates of multiple elements among multiple crystallographic sites in clinopyroxene, combined with fast cooling upon eruption, act to preserve the oscillatory zoning. Oscillatory zoning of P in olivine is a product of solute trapping resulting from the slow diffusion of P in silicate melts and minerals, and relatively fast magma cooling rates that may be related to magma chamber convection. Differential cooling of the chamber and the fast cooling rates within the chamber are likely a product of the thermal state of the lunar crust at 2.93 Ga when NWA 032, which is currently the youngest dated lunar igneous rock, erupted onto the surface of the Moon.

Published

2014

88. The origin of young mare basalts inferred from lunar meteorites Northwest Africa 4734, 032, and LaPaz Icefield 02205

Author

Francis M. McCubbin, Lars E. Borg, Vera A. Fernandes, Stephen M. Elardo, Amy M. Gaffney, Paul V. Burger, Clive R. Neal, Charles K. Shearer, and A. L. Fagan

Subjects

Basalt, Isochron, Lunar meteorite, Geophysics, Meteorite, Space and Planetary Science, Lava, Partial melting, Geochemistry, KREEP, Chemical composition, Geology

Abstract

Northwest Africa (NWA) 4734 is an unbrecciated basaltic lunar meteorite that is nearly identical in chemical composition to basaltic lunar meteorites NWA 032 and LaPaz Icefield (LAP) 02205. We have conducted a geochemical, petrologic, mineralogic, and Sm-Nd, Rb-Sr, and Ar-Ar isotopic study of these meteorites to constrain their petrologic relationships and the origin of young mare basalts. NWA 4734 is a low-Ti mare basalt with a low Mg* (36.5) and elevated abundances of incompatible trace elements (e.g., 2.00 ppm Th). The Sm-Nd isotope system dates NWA 4734 with an isochron age of 3024 ± 27 Ma, an initial eNd of +0.88 ± 0.20, and a source region 147Sm/144Nd of 0.201 ± 0.001. The crystallization age of NWA 4734 is concordant with those of LAP 02205 and NWA 032. NWA 4734 and LAP 02205 have very similar bulk compositions, mineral compositions, textures, and ages. Their source region 147Sm/144Nd values indicate that they are derived from similar, but distinct, source materials. They probably do not sample the same lava flow, but rather are similarly sourced, but isotopically distinct, lavas that probably originate from the same volcanic complex. They may have experienced slightly different assimilation histories in route to eruption, but can be source-crater paired. NWA 032 remains enigmatic, as its source region 147Sm/144Nd definitively precludes a simple relationship with NWA 4734 and LAP 02205, despite a similar bulk composition. Their high Ti/Sm, low (La/Yb)N, and Cl-poor apatite compositions rule out the direct involvement of KREEP. Rather, they are consistent with low-degree partial melting of late-formed LMO cumulates, and indicate that the geochemical characteristics attributed to urKREEP are not unique to that reservoir. These and other basaltic meteorites indicate that the youngest mare basalts originate from multiple sources, and suggest that KREEP is not a prerequisite for the most recent known melting in the Moon.

Published

2014

89. PETROLOGY AND MINERALOGY OF LUNAR METEORITE MIL 090070 FROM ANTARCTICA

Author

Zhipeng Xia, Hongyi Chen, Jie Yao, Bingkui Miao, and Lanfang Xie

Subjects

Lunar meteorite, Atmospheric Science, Ecology, Geochemistry, Geology, Petrology

Published

2014

90. PETROGRAPHY AND MINERALOGY OF A NEW LUNAR METEORITE MIL 090036

Author

Lanfang Xie, Bingkui Miao, Hongyi Chen, Zhipeng Xia, and Jie Yao

Subjects

Lunar meteorite, Petrography, Atmospheric Science, Ecology, Geochemistry, Geology, Petrology

Published

2014

91. THE PETROLOGY AND MINERALOGY OF LUNAR METEORITE EET 96008 FROM ANTARCTICA

Author

Zhipeng Xia, Bingkui Miao, Hongyi Chen, Lanfang Xie, and Jie Yao

Subjects

Lunar meteorite, Atmospheric Science, Ecology, Geology, Petrology, Astrobiology

Published

2014

92. U-Pb zircon dating of the lunar meteorite Dhofar 1442

Author

Yu. A. Kostitsyn, Mikhail A. Nazarov, F. Brandstaetter, S. I. Demidova, Th. Ntaflos, and M. O. Anosova

Subjects

Basalt, Lunar meteorite, Geochemistry, KREEP, engineering.material, Meteorite, Geochemistry and Petrology, Clastic rock, Breccia, engineering, Petrology, Ilmenite, Geology, Zircon

Abstract

Dhofar 1442 is one of the few lunar KREEP-rich meteorites, which contains KREEP norites and KREEP gabbronorite as well as low-Ti basalts and highly evolved granophyres. Zircon is a typical accessory mineral of KREEP rocks. U-Th-Pb dates of 12 zircon grains (four of them were in two lithic clasts, and the others were fragments in the meteorite matrix) indicate that the zircons belong to at least two groups of different age: “ancient” (∼4.31 Ga) and “young” (∼3.95 Ga), which correspond to two major pulses of KREEP magmatism in the source region of the Dhofar 1442 meteorite. The zircon of the “young” group was most probably related to the crater ejecta of the Mare Imbrium Basin. The rock fragments dated at approximately 3.95 Ga have the composition of KREEP gabbronorite. The parental rocks of the zircon of the “ancient” group in the Dhofar 1442 meteorite are uncertain and could be highly evolved granophyres. This hypothesis is supported by the high Th (100–300 ppm) and U (150–400 ppm) contents. These zircon fragments of the “ancient” group, higher than in the “young” group (

Published

2014

93. Implications for the origins of pure anorthosites found in the feldspathic lunar meteorites, Dhofar 489 group

Author

Nagaoka, Hiroshi, Takeda, Hiroshi, Karouji, Yuzuru, Ohtake, Makiko, Yamaguchi, Akira, Yoneda, Shigekazu, and Hasebe, Nobuyuki

Published

2014

94. Geochemistry and mineralogy of a feldspathic lunar meteorite (regolith breccia), Northwest Africa 2200

Author

Nobuyuki Hasebe, Hiroshi Nagaoka, Yuzuru Karouji, Mitsuru Ebihara, and Tomoko Arai

Subjects

Lunar meteorite, Incompatible element, Mineral, Ecology, Geochemistry, KREEP, Earth and Planetary Sciences(all), Aquatic Science, Mineralogy, Regolith, Anorthosite, Meteorite, Breccia, Ferroan anorthosite, General Earth and Planetary Sciences, Petrology, Geology, Ecology, Evolution, Behavior and Systematics

Abstract

The lunar meteorite Northwest Africa (NWA) 2200 is a regolith breccia with a ferroan feldspathic bulk composition (Al2O3 = 30.1 wt.%; Mg# = molar 100 × Mg/(Mg + Fe) = 59.2) and low Th content (0.42 μg/g). Lithologically, NWA 2200 is a diverse mixture of lithic and glassy clasts, mineral fragments, and impact glass spherules, all embedded in a dark glassy matrix. NWA 2200 contains some feldspathic brecciated rock components (ferroan anorthositic granulitic breccia, poikiloblastic granulitic breccia, and glassy melt breccia with an intersertal texture). The bulk compositions of these brecciated components indicate they are derived from ferroan troctolitic or noritic anorthosite lithologies (bulk Al2O3 = 26–30 wt.%; bulk FeO/MgO > 1.0). The bulk composition of NWA 2200 is more ferroan and feldspathic than the Apollo feldspathic regolith samples and feldspathic lunar regolith meteorites, and is also more depleted in incompatible elements (e.g., rare earth elements) than Apollo 16 feldspathic regolith samples. We conclude that NWA 2200 originated from a location different to the Apollo landing sites, and may have been sourced from the ferroan KREEP-poor highlands, “KREEP” materials are enriched in such elements as potassium (K), rare earth elements (REE), phosphorus (P).

Published

2013

95. New lunar meteorite Northwest Africa 2996: A window into farside lithologies and petrogenesis

Author

Katherine H. Joy, Celestine N. Mercer, and Allan H. Treiman

Subjects

Lunar meteorite, Basalt, Incompatible element, Geochemistry, KREEP, engineering.material, Anorthosite, Geophysics, Space and Planetary Science, Breccia, engineering, Plagioclase, Mafic, Petrology, Geology

Abstract

The Northwest Africa (NWA) 2996 meteorite is a lunar regolith breccia with a “mingled” bulk composition and slightly elevated incompatible element content. NWA 2996 is dominated by clasts of coarse-grained noritic and troctolitic anorthosite containing calcic plagioclase (An#~98) and magnesian mafic minerals (Mg#~75), distinguishing it from Apollo ferroan anorthosites and magnesian-suite rocks. This meteorite lacks basalt, and owes its mingled composition to a significant proportion of coarse-grained mafic clasts. One group of mafic clasts has pyroxenes similar to anorthosites, but contains more sodic plagioclase (An#~94) distinguishing it as a separate lithology. Another group contains Mg-rich, very low-titanium pyroxenes, and could represent an intrusion parental to regional basalts. Other clasts include granophyric K-feldspar, disaggregated phosphate-bearing quartz monzodiorites, and alkali-suite fragments (An#~65). These evolved lithics are a minor component, but contain minerals rich in incompatible elements. Several anorthosite clasts contain clusters of apatite, suggesting that the anorthosites either assimilated evolved rocks or were metasomatized by a liquid rich in incompatible elements. We used Lunar Prospector gamma-ray spectrometer remote sensing data to show that NWA 2996 is most similar to regoliths in and around the South Pole Aitken (SPA) basin, peripheral regions of eastern mare, Nectaris, Crisium, and southern areas of Mare Humorum. However, the mineralogy of NWA 2996 is distinctive compared with Apollo and Luna mission samples, and is likely consistent with an origin near the SPA basin: anorthosite clasts could represent local crustal material, mafic clasts could represent intrusions beneath basalt flows, and apatite-bearing rocks could carry the SPA KREEP signature.

Published

2013

96. Petrogenesis of the Northwest Africa 4898 high-Al mare basalt

Author

Yunbin Guan, Weibiao Hsu, Shaolin Li, Linyan Wang, and Ying Wang

Subjects

Basalt, Lunar meteorite, Fractional crystallization (geology), Olivine, 010504 meteorology & atmospheric sciences, Geochemistry, Maskelynite, Pyroxene, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Space and Planetary Science, engineering, Plagioclase, Phenocryst, Geology, 0105 earth and related environmental sciences

Abstract

Northwest Africa (NWA) 4898 is the only low-Ti, high-Al basaltic lunar meteorite yet recognized. It predominantly consists of pyroxene (53.8 vol%) and plagioclase (38.6 vol%). Pyroxene has a wide range of compositions (En_(12–62)Fs_(25–62)Wo_(11–36)), which display a continuous trend from Mg-rich cores toward Ca-rich mantles and then to Fe-rich rims. Plagioclase has relatively restricted compositions (An_(87–96)Or_(0–1)Ab_(4–13)), and was transformed to maskelynite. The REE zoning of all silicate minerals was not significantly modified by shock metamorphism and weathering. Relatively large (up to 1 mm) olivine phenocrysts have homogenous inner parts with Fo ~74 and sharply decrease to 64 within the thin out rims (~30 μm in width). Four types of inclusions with a variety of textures and modal mineralogy were identified in olivine phenocrysts. The contrasting morphologies of these inclusions and the chemical zoning of olivine phenocrysts suggest NWA 4898 underwent at least two stages of crystallization. The aluminous chromite in NWA 4898 reveals that its high alumina character was inherited from the parental magma, rather than by fractional crystallization. The mineral chemistry and major element compositions of NWA 4898 are different from those of 12038 and Luna 16 basalts, but resemble those of Apollo 14 high-Al basalts. However, the trace element compositions demonstrate that NWA 4898 and Apollo 14 high-Al basalts could not have been derived from the same mantle source. REE compositions of its parental magma indicate that NWA 4898 probably originated from a unique depleted mantle source that has not been sampled yet. Unlike Apollo 14 high-Al basalts, which assimilated KREEPy materials during their formation, NWA 4898 could have formed by closed-system fractional crystallization.

Published

2016

97. The lunar highlands: old crust, new ideas

Author

John F Pernet-Fisher and Katherine H Joy

Subjects

Lunar meteorite, Moon, Crust

Published

2016

98. High crustal diversity preserved in the lunar meteorite Mount DeWitt 12007 (Victoria Land, Antarctica)

Author

Andreas Pack, Alberto Collareta, Massimo D'Orazio, Luigi Folco, and Maurizio Gemelli

Subjects

Basalt, Lunar meteorite, Incompatible element, 010504 meteorology & atmospheric sciences, mingled breccia, Geochemistry, Pyroxene, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, lunar regolith, Volcanic glass, Geophysics, DEW 12007, mingled breccia, lunar regolith, Moon, Antarctica, Meteorite, Space and Planetary Science, Breccia, DEW 12007, engineering, Plagioclase, Antarctica, Moon, Geology, 0105 earth and related environmental sciences

Abstract

The meteorite Mount DeWitt (DEW) 12007 is a polymict regolith breccia mainly consisting of glassy impact-melt breccia particles, gabbroic clasts, feldspathic clasts, impact and volcanic glass beads, basaltic clasts, and mingled breccia clasts embedded in a matrix dominated by fine-grained crystals; vesicular glassy veins and rare agglutinates are also present. Main minerals are plagioclase (typically An>85) and clinopyroxene (pigeonites and augites, sometimes interspersed). The presence of tranquillityite, coupled with the petrophysical data, the O-isotope data (Δ17O = −0.075), and the FeOtot/MnO ratios in olivine (91), pyroxene (65), and bulk rock (77) indicate a lunar origin for DEW 12007. Impactites consist of Al-rich impact-melt splashes and plagioclase-rich meta-melt clasts. The volcanic products belong to the very low titanium (VLT) or low titanium (LT) suites; an unusual subophitic fragment could be cryptomare-related. Gabbroic clasts could represent part of a shallow intrusion within a volcanic complex with prevailing VLT affinity. DEW 12007 has a mingled bulk composition with relatively high incompatible element abundances and shows a high crustal diversity comprising clasts from the Moon's major terranes and rare lithologies. First-order petrographic and chemical features suggest that DEW 12007 could be launch-paired with other meteorites including Y 793274/981031, QUE 94281, EET 87521/96008, and NWA 4884.

Published

2016

99. Native silicon and iron silicides in the Dhofar 280 lunar meteorite

Author

Th. Ntaflos, F. Brandstaetter, Yu. A. Kostitsyn, S. I. Demidova, Mikhail A. Nazarov, and M. O. Anosova

Subjects

Lunar meteorite, Silicon, Geochemistry, chemistry.chemical_element, Mineralogy, Crust, Silicate, chemistry.chemical_compound, chemistry, Meteorite, Geochemistry and Petrology, Lithophile, Volatiles, Geology, Refractory (planetary science)

Abstract

The Dhofar 280 lunar highland meteorite is the first one in which native silicon was identified in association with iron silicides. This association is surrounded by silicate material enriched in Si, Na, K, and S and occurs within an impact-melt matrix. Compared to the meteorite matrix, the objects with native Si and the silicate material around them show high Al-normalized concentrations of volatile elements and/or elements with low sensitivity to oxygen but are not any significantly enriched in refractory lithophile elements. Some lithophile elements (V, U, Sm, Eu, and Yb) seem to be contained in reduced forms, and this predetermines REE proportions atypical of lunar rocks and a very low Th/U ratio. The admixture of siderophile elements (Ni, Co, Ge, and Sb) suggests that the Si-bearing objects were contaminated with meteorite material and were produced by the impact reworking of lunar rocks. The high concentrations of volatile elements suggest that the genesis of these objects could be related to the condensation of silicate vapor generated during meteorite impacts. The reduction of silicon and other elements could take place in an impact vapor cloud, with the subsequent condensation of these elements together with volatile components. On the other hand, condensates of silicate vapor could be reduced by impact reworking of impact breccias. Impact-induced vaporization and condensation seem not to play any significant role in forming the composition of the lunar crust, but the contents of the products of such processes can be locally relatively high. The greatest amounts of silicate vapor were generated during significant impact events. For example, more than 70% of the total mass of lunar material evaporated in the course of impact events should have resulted from the collision of the Moon with a cosmic body that produced the Moon’s largest South Pole-Aitken basin.

Published

2012

100. Petrogenesis of the Northwest Africa 4734 basaltic lunar meteorite

Author

Yu Liu, Qiu-Li Li, Yunbin Guan, Guo-Qiang Tang, Weibiao Hsu, Xian-Hua Li, and Ying Wang

Subjects

Lunar meteorite, Basalt, Olivine, Meteorite, Geochemistry and Petrology, engineering, Geochemistry, Plagioclase, Pyroxene, engineering.material, Geology, Baddeleyite, Petrogenesis

Abstract

We report the petrography, mineralogy, trace element abundance geochemistry, and Pb–Pb geochronology of the lunar meteorite Northwest Africa (NWA) 4734 and make a comparison with the LaPaz Icefield (LAP) 02205/02224 low-Ti lunar basaltic meteorites. NWA 4734 is an unbrecciated low-Ti mare basalt composed mainly of subophitic-textured pyroxene (60 vol%) and plagioclase (30%). Pyroxene, plagioclase, and olivine exhibit large compositional variations and intra-grain chemical zoning. Pyroxene and plagioclase in NWA 4734 have rare earth element (REE) concentrations and patterns similar to those of the LAPs. The crystallization age of NWA 4734, determined in situ in baddeleyite, is 3073 ± 15 Ma (2σ), nearly identical to that of the LAPs (3039 ± 12 Ma). NWA 4734 and the LAPs have similar textures, modal abundances, mineral chemistry, and crystallization ages, and are most likely source-crater paired on the Moon. One baddeleyite grain in LAP 02224 displays distinctively older and spatially variable ages, from 3349 ± 62 to 3611 ± 62 Ma (2σ), similar to another baddeleyite grain (3109 ± 29 to 3547 ± 21 Ma) reported by Zhang et al. (2010) for the same meteorite. Raman spectra, cathodoluminescence, and stoichiometric studies of the baddeleyite suggest that the two older grains were not endogenic but were trapped by the parental magma. Equilibrium partition calculation shows that the parental melt from which the NWA 4734 plagioclase crystallized has much lower REE contents than its whole rock, indicating an open system during magma evolution. NWA 4734 could have originated from a parental melt with REE concentrations similar to that of the Apollo 12 olivine basalt. The magma likely assimilated a small amount (∼4 wt%) of KREEP-rich material during its ascent through the lunar crust.

Published

2012