Your search keyword '"Lunar meteorite"' showing total 80 results

1. Subsolidus breakdown of armalcolite: Constraints on thermal effects during shock lithification of lunar regolith.

Author

Du, Tian-Ran Trina, Zhang, Ai-Cheng, Chen, Jia-Ni, and Wen, Yuan-Yun

Subjects

*LUNAR soil, *METEORITES, *BRECCIA, *ILMENITE, *PLANETARY surfaces, *REGOLITH, *MINERALS

Abstract

Shock lithification of regolith breccias is a ubiquitous process on the surfaces of airless planetary bodies and may induce thermal effects, including melting on regolith breccia minerals. However, potential thermal effects on lithic and mineral clasts in regolith breccias have seldom been quantitatively constrained. Here, we report two types of micro-textures of armalcolite [(Mg,Fe2+)Ti2O5] in an Mg-suite lithic clast from lunar regolith breccia meteorite Northwest Africa 8182. One type of armalcolite contains oriented fine-grained ilmenite grains; the other occurs as an aggregate of ilmenite, rutile, spinel, and loveringite. We propose that the two types of micro-textures formed through subsolidus breakdown of armalcolite by different processes. The formation of ilmenite inclusions in armalcolite is related to slow cooling after the solidification of its source rock, whereas the ilmenite-rutile-spinel-loveringite aggregates probably formed during the shock lithification event of NWA 8182. The results indicate that the temperature at the margin of lithic clasts could be raised up to at least 600 °C during strong shock lithification of lunar regolith and has profound thermal effects on the mineralogical and isotopic behaviors of lithic and mineral fragments in lunar regolith breccias. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

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

Subjects

breccia, lunar magma, lunar meteorite, NWA 10049, zircon, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract The temporal duration of lunar‐evolved magmatism is still poorly constrained. In lunar meteorite Northwest Africa (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

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

Author

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

Subjects

*ZIRCON, *BRECCIA, *METEORITES, *ZIRCON analysis, *MELTING, *MOON, *MELTING points, *OLD age

Abstract

The temporal duration of lunar‐evolved magmatism is still poorly constrained. In lunar meteorite Northwest Africa (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; <0.5 wt% FeO), compositionally similar with immiscible silica‐rich melts found in Apollo rocks. Nano‐SIMS U–Pb analyses of the zircon yielded a minimum crystallization age of 4,382 ± 40 Ma, older than the ages for Apollo highly evolved alkali suite lithologies (~3.8–4.33 Ga). Our study shows that the melt inclusion‐bearing zircon in NWA 10049 is the oldest microscale evidence for documenting immiscible silica‐rich melts in lunar samples, suggesting that lunar‐evolved silica‐rich melts were prevalent as early as ~4.38 Ga. This work implies that there would be a prolonged silicic magmatism occurred on the Moon. Plain Language Summary: Lunar‐evolved silica‐rich melt is thought to be related to the formation of highly silicic lithologies (e.g., granitic lithologies). These rock types have been observed in Apollo returned samples as lithic clasts and also have been detected by remote‐sensing data as silicic domes. The Apollo‐evolved lithologies give a wide range of crystallization ages from ~3.8–4.33 Ga. However, there is still unclear about the temporal duration of lunar‐evolved magmatism and volcanism. In lunar meteorite breccia NWA 10049, a melt inclusions‐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 compositionally similar with immiscible silica‐rich melts found in Apollo rocks. Nano‐SIMS U–Pb analyses of the zircon yielded a minimum crystallization age of ~4.38 Ga. This age is older than the ages for Apollo‐returned granites (up to 4.33 Ga) and ancient basaltic volcanism (i.e., up to ~4.37 Ga), making the studied zircon is the oldest microscale evidence for documenting lunar silicate liquid immiscibility. Key Points: A ~200‐μm‐sized melt inclusion‐bearing zircon fragment was found in lunar feldspathic breccia meteorite NWA 10049Melt inclusions in this zircon are compositionally consistent with lunar immiscible silica‐rich meltsThe zircon is 4.38 Ga and provides microscale evidence for ancient immiscible silica‐rich melt on the Moon [ABSTRACT FROM AUTHOR]

Published

2020

4. An ancient reservoir of volatiles in the Moon sampled by lunar meteorite Northwest Africa 10989

Author

G. Q. Tang, S. Hu, Xuchao Zhao, Emma Humphreys-Williams, H. O. Ashcroft, Y. Liu, Stanislav Strekopytov, Ian A. Franchi, A. Stephant, Mahesh Anand, Richard C. Greenwood, Q. L. Li, and Randy L. Korotev

Subjects

Basalt, Lunar meteorite, 010504 meteorology & atmospheric sciences, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Isotopic composition, Apatite, Meteorite, Geochemistry and Petrology, visual_art, Breccia, visual_art.visual_art_medium, Geology, 0105 earth and related environmental sciences

Abstract

Northwest Africa (NWA) 10989 is a recently found lunar meteorite we used to elucidate the history of volatiles (H and Cl) in the Moon through analysis of its phosphates. The petrology, bulk geochemistry and mineralogy of NWA 10989 are consistent with it being a lunar meteorite with intermediate-iron bulk composition, composed of 40% of mare basaltic material and ∼60% non-mare material, but with no obvious KREEP-rich basaltic components. It is probable that the source region for this meteorite resides near a mare–highlands boundary, possibly on the farside of the Moon. Analyses of chlorine and hydrogen abundances and isotopic composition in apatite and merrillite grains from NWA 10989 indicate sampling of at least two distinct reservoirs of volatiles, one being similar to those for known mare basalts from the Apollo collections, while the other potentially represents a yet unrecognized reservoir. In situ Th-U-Pb dating of phosphates reveal two distinct age clusters with one ranging from 3.98 ± 0.04 to 4.20 ± 0.02 Ga, similar to the ages of cryptomare material, and the other ranging from 3.32 ± 0.01 to 3.96 ± 0.03 Ga, closer to the ages of mare basalts known from the Apollo collections. This lunar breccia features mixing of material, among which a basaltic D-poor volatile reservoir which doesn’t appear to have been recorded by Apollo samples.

Published

2019

5. New lunar meteorite<scp>NWA</scp>10986: A mingled impact melt breccia from the highlands—A complete cross section of the lunar crust

Author

S. E. Roberts, M. M. Jean, Lawrence A. Taylor, and Molly C. McCanta

Subjects

Lunar meteorite, Cross section (physics), Geophysics, Space and Planetary Science, Breccia, Geochemistry, Crust, Geology

Published

2019

6. 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

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

Author

Ryan A. Zeigler, Fred Jourdan, Yusheng Wan, Martin J. Whitehouse, M. L. Grange, Nicholas E. Timms, Joshua F. Snape, Tao Long, Bradley L. Jolliff, Dunyi Liu, and Alexander A. Nemchin

Subjects

Basalt, Lunar meteorite, 010504 meteorology & atmospheric sciences, biology, Near side of the Moon, Apollo, Geochemistry, 010502 geochemistry & geophysics, biology.organism_classification, 01 natural sciences, Geophysics, Geochemistry and Petrology, Asteroid, Clastic rock, Breccia, Ejecta, Geology, 0105 earth and related environmental sciences

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 ages available for impact melt samples from different landing sites and obtained using the step-heating technique, suggests that the majority of the samples that gave robust plateau ages are indistinguishable within uncertainties and altogether yield a weighted average age of 3916 ± 7 Ma (95 % conf., MSWD = 1.1; P = 0.13) and a median average age of 3919 + 14/-12 Ma, both of which agree with the confidence interval obtained using the U-Pb system. These samples, dated by 40Ar/39Ar method, can be also viewed as representing the Imbrium impact. In total 36 out of 41 breccia samples from five landing sites can be interpreted to represent formation of the Imbrium basin, supporting the conclusion that Imbrium material was distributed widely across the near side of the Moon. Establishing temporal limits for the Imbrium impact allows discrimination of ten samples with Rb-Sr and 40Ar/39Ar ages about 50 Ma younger than 3922 ± 12 Ma. This group may represent a separate single impact on the Moon and needs to be investigated further to improve our understanding of lunar impact history.

Published

2021

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

Author

Mahajan, Ramakant R.

Subjects

*LUNAR meteorites, *NOBLE gases, *REGOLITH, *BRECCIA, *COSMIC rays, *ATMOSPHERIC nitrogen

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, 20 Ne=3.69×10 −3 , 36 Ar=12.6×10 −4 , 84 kr=8.57×10 −7 and 132 Xe=1.63×10 −7 ccSTP/g. The cosmic-ray exposure ages for Y-983885 are thus calculated to be T 21 (A)=1592±232 Ma and T 21 (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 ( T 21 (A)=1592±232 Ma and T 21 (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 20 Ne/ 22 Ne 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. [ABSTRACT FROM AUTHOR]

Published

2015

9. The lunar Dhofar 1436 meteorite: 40Ar‐39Ar chronology and volatiles, revealed by stepwise combustion and crushing methods

Author

A. V. Korochantsev, A. I. Buikin, Jens Hopp, A. B. Verchovsky, Ekaterina V. Korochantseva, Mahesh Anand, Mario Trieloff, Korochantseva, Ekaterina V., 1Institut für Geowissenschaften Klaus‐Tschira‐Labor für Kosmochemie Universität Heidelberg Im Neuenheimer Feld 234‐236 69120 Heidelberg Germany, Buikin, Alexei I., 2Vernadsky Institute of Geochemistry Kosygin St. 19 119991 Moscow Russia, Hopp, Jens, Verchovsky, Alexander B., 3School of Physical Sciences The Open University Milton Keynes MK7 6AA UK, Korochantsev, Alexander V., and Anand, Mahesh

Subjects

Lunar meteorite, 551.9, Materials science, 549.112, Geochemistry, chemistry.chemical_element, argon isotope data, 010502 geochemistry & geophysics, 01 natural sciences, Shock metamorphism, lunar meteorite Dhofar 1436, 0103 physical sciences, Breccia, 010303 astronomy & astrophysics, Late Heavy Bombardment, 0105 earth and related environmental sciences, Radiogenic nuclide, Argon, impact melt breccia, Regolith, noble gas measurements, Geophysics, Meteorite, chemistry, Space and Planetary Science, 523.51

Abstract

The lunar meteorite Dhofar 1436 is dominated by solar wind type noble gases. Solar argon is equilibrated with “parentless” 40Ar commonly known as lunar orphan argon. Ar‐Ar isochron analyses determined the lunar trapped 40Ar/36Ar ratio to 2.51 ± 0.04, yielding a corrected plateau age of 4.1 ± 0.1 Ga, consistent with the lunar Late Heavy Bombardment period. Lunar trapped and radiogenic argon components are all released at high temperatures (1200–1400 °C). Surprisingly, solar noble gases and lunar trapped argon can largely be released by crushing. Initial crushing steps mainly release elementally fractionated solar wind gases, while in advanced crushing steps, cosmogenic components dominate. Cosmogenic noble gases indicate irradiation at the lunar surface; they are less fractionated than solar wind species. We favor a scenario in which both solar and a large fraction of cosmogenic gases were acquired before the 4.1 Ga event, which caused shock metamorphism and formation of the regolith breccia. Sintering and agglutination along grain boundaries resulted in mobilization of solar wind, reimplanted, radiogenic, and cosmogenic noble gases, and resulted in their partial homogenization, fractionation, and retrapping in voids and/or defects accessible by crushing. An alternative scenario would be complete reset of the K‐Ar system 4.1 Ga ago accompanied by loss of all previously accumulated solar and cosmogenic noble gases. Later, the precursor of Dhofar 1436 became lunar regolith and accumulated solar and cosmogenic noble gases and reimplanted 40Ar before its final formation of the polymict impact breccia. The C abundance of the step‐combusted Dhofar 1436 is 555.3 ppm, with δ13C of −28‰ to +11‰. Nitrogen contents released by crushing and combustion are 3.2 ppm and 20.8 ppm, respectively. The lightest nitrogen composition (δ15N = −79‰) is likely due to release from voids of shock metamorphic phases and is rather a result of the mobilization of nitrogen components that accumulated prior to the 4.1 Ga event., Klaus Tschira Stiftung http://dx.doi.org/10.13039/501100007316

Published

2021

10. Lunar meteorite Northwest Africa 11962: A regolith breccia containing records of titanium‐rich lunar volcanism and the high alkali suite

Author

Andreas Bechtold, Ludovic Ferrière, Franz Brandstätter, Lidia Pittarello, Richard C. Greenwood, and Christian Koeberl

Subjects

Basalt, Lunar meteorite, Felsite, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Regolith, Petrography, Geophysics, Meteorite, Space and Planetary Science, Clastic rock, 0103 physical sciences, Breccia, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

The meteorite Northwest Africa (NWA) 11962 has been recently classified as a lunar regolith breccia. For the present study, the clasts and the matrix of NWA 11962 have been characterized by optical and electron microscopy along with electron microprobe analyses. The meteorite has a glassy impact melt matrix, which accounts for 35% of the surface area in the thin sections examined, and which contains a very large variety of different lithic clasts, monomineralic clasts, and glass fragments. Lithic clasts include numerous fragments of quartz monzogabbro and lunar felsite, which are quite rare lithologies in the lunar alkali suite. However, the most abundant component in the breccia are gabbroic clasts. The mineral chemistry of the pyroxenes in these gabbroic clasts and the chemistry of various types of glasses in the breccia indicate an origin of the regolith from an area with low-Ti to high-Ti mare basalt volcanism. In addition to the peculiar petrographic characteristics of NWA 11962, the possible pairing relation with the NWA 4472/4485 group of lunar meteorites is discussed.

Published

2021

11. 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

12. 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

13. 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

14. 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

15. 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

16. 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

17. 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

18. 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

19. 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

20. 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

21. 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

22. 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

23. 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

24. 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

25. 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

26. 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

27. Lunar meteorites from Oman

Author

Randy L. Korotev

Subjects

Basalt, Lunar meteorite, Igneous rock, Geophysics, Meteorite, Space and Planetary Science, Clastic rock, Breccia, Geochemistry, Achondrite, Geology, Astrobiology

Abstract

– Sixty named lunar meteorite stones representing about 24 falls have been found in Oman. In an area of 10.7 × 103 km2 in southern Oman, lunar meteorite areal densities average 1 g km−2. All lunar meteorites from Oman are breccias, although two are dominated by large igneous clasts (a mare basalt and a crystalline impact-melt breccia). Among the meteorites, the range of compositions is large: 9–32% Al2O3, 2.5–21.1% FeO, 0.3–38 μg g−1 Sm, and

Published

2012

28. Very high-K KREEP-rich clasts in the impact melt breccia of the lunar meteorite SaU 169: New constraints on the last residue of the Lunar Magma Ocean

Author

Guo-Qiang Tang, Wenjie Shen, Beda A. Hofmann, Xian-Hua Li, Yangting Lin, Fu-Yuan Wu, Q. Mao, Yushuo Liu, and Liying Xu

Subjects

Lunar meteorite, 010504 meteorology & atmospheric sciences, Geochemistry, KREEP, Maskelynite, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Shock metamorphism, Meteorite, Lunar magma ocean, 13. Climate action, Geochemistry and Petrology, Breccia, engineering, Geology, 0105 earth and related environmental sciences, Zircon

Abstract

In the impact melt breccia (IMB) of Sayh al Uhaymir (SaU) 169, the most KREEP-rich lunar meteorite to date ( Gnos et al., 2004 ), clasts of a new type of lithologies were discovered, consisting of Ca-poor and Ca-rich pyroxenes (60.8 vol.%), Ba-rich K-feldspar (27.9 vol.%), phosphates (5.6 vol.%), Nb-rich ilmenite (4.0 vol.%), zircon (1.2 vol.%) and minor sulfide (0.6 vol.%). These mafic lithic clasts are more enriched in KREEP component (∼1500 × CI) than the host meteorite and are highly enriched in potassium. They are referred to as very high-K (VHK) KREEP lithology, and probably most close to the last residual liquid of the Lunar Magma Ocean without significant dilution by other Mg-rich magmas. The fine-grained matrix of the SaU 169 IMB has very similar mineral chemistry to the VHK KREEP lithology, but contains abundant plagioclase with trace K-feldspar. The matrix shows decoupling of K from the REEP-like component; however, it cannot be simply interpreted by mixing the VHK KREEP lithology with anorthosites, which should have diluted the REEP-like component with the same proportion. SIMS Pb–Pb dating was conducted on zircons in various petrographic settings and with different crystal habits. All analyses show a main age peak at 3921 ± 3 Ma and a smaller one at 4016 ± 6 Ma. The main age peak is identical to the previous Pb–Pb age by Gnos et al. (2006) and U–Pb age by Liu et al. (2009) , dating the catastrophic shock event contributed to the formation of SaU 169 IMB. The older ages are consistent with the previous report of an older bulk U–Pb age by Kramers et al. (2007) , suggestive of presence of relict crystals in a few large zircon grains. The VHK KREEP clasts predated the fine-grained matrix, but have the same zircon Pb–Pb ages as the latter within the analytical uncertainties. Plagioclase was converted to maskelynite whereas zircon was shocked to diaplectic glass, probably by a second event at ∼2.8 Ga. However, the identical zircon Pb–Pb ages of the amorphous parts and the remained crystalline areas indicate no resetting of Pb–Pb isotopes by the later shock metamorphism, or there was another severe impact event postdated solidification of the fine-grained matrix within a few million years.

Published

2012

29. Comparative zircon U–Pb geochronology of impact melt breccias from Apollo 12 and lunar meteorite SaU 169, and implications for the age of the Imbrium impact

Author

Ryan A. Zeigler, Wei Wang, Dunyi Liu, Bradley L. Jolliff, Hangqiang Xie, Yuhai Zhang, Chunyan Dong, Yushan Wan, and Randy L. Korotev

Subjects

Lunar meteorite, biology, Apollo, Geochemistry, KREEP, biology.organism_classification, Geophysics, Meteorite, Space and Planetary Science, Geochemistry and Petrology, Geochronology, Breccia, Earth and Planetary Sciences (miscellaneous), Geology, Zircon, Terrane

Abstract

The ages of zircons from high-Th impact-melt breccias (IMBs) from meteorite Sayh al Uhaymir (SaU) 169 and from rock fragments in soil samples from Apollo 12 have been determined using the SHRIMP-II ion microprobe. The IMBs are very similar to each other in chemistry, mineralogy and texture, and the zircons from the KREEP-rich (high-Th) crystalline impact melt have similar U and Th contents and identical ages, within uncertainties, of 3920 ± 13 (2σ) Ma (SaU 169) and 3914 ± 7 (2σ) Ma (Apollo 12). The age results support the idea that the high-Th IMBs (Apollo 12 and SaU 169) formed in the same impact event. The similarity of composition and age suggest that SaU 169 and the high-Th IMB fragments of Apollo 12 originated from the same area of the Procellarum KREEP Terrane. We interpret the age of zircon grains in the Apollo 12 high-Th IMB as a precise and direct determination of the age of the Imbrium impact. This age is significantly older than the commonly cited age of 3.85 Ga but is similar to recent determinations from SIMS U–Pb dating of Apollo 14 apatite grains and with anticipated revision of ages by 40 Ar– 39 Ar and 87 Rb– 86 Sr. The present zircon 207 Pb– 206 Pb age is the first direct zircon age determination of the Imbrium impact event from an Apollo sample. Previous measurements of zircon ages of Apollo IMBs have recorded events pre-dating the Imbrium basin-forming event.

Published

2012

30. Characterization of multiple lithologies within the lunar feldspathic regolith breccia meteorite Northeast Africa 001

Author

Katherine H. Joy, Joshua F. Snape, and Ian A. Crawford

Subjects

Basalt, Lunar meteorite, Anorthosite, Geophysics, Lunar magma ocean, Meteorite, Space and Planetary Science, Breccia, Geochemistry, KREEP, Regolith, Geology

Abstract

Lunar meteorite Northeast Africa (NEA) 001 is a feldspathic regolith breccia. This study presents the results of electron microprobe and LA-ICP-MS analyses of a section of NEA 001. We identify a range of lunar lithologies including feldspathic impact melt, ferroan noritic anorthosite and magnesian feldspathic clasts, and several very-low titanium (VLT) basalt clasts. The largest of these basalt clasts has a rare earth element (REE) pattern with light-REE (LREE) depletion and a positive Euanomaly. This clast also exhibits low incompatible trace element (ITE) concentrations (e.g.

Published

2011

31. Mineralogy, geochemistry, and 40Ar–39Ar geochronology of lunar granulitic breccia Northwest Africa 3163 and paired stones: Comparisons with Apollo samples

Author

Randy L. Korotev, John G. Spray, Jillian A. Hudgins, and Simon P. Kelley

Subjects

Lunar meteorite, Recrystallization (geology), Geochemistry, Mineralogy, engineering.material, Granulite, Meteorite, Geochemistry and Petrology, Geochronology, Breccia, engineering, Plagioclase, Late Heavy Bombardment, Geology

Abstract

The lunar meteorites Northwest Africa (NWA) 3163, 4881, and 4483 are paired stones classified as granulitic breccias. At 2.4 kg, these three stones constitute one of the largest known lunar meteorite masses. Here we describe the petrography, mineralogy, and chemistry of NWA 3163, 4881, and 4483, and present 40 Ar– 39 Ar data for two of the meteorites. Two-pyroxene thermometry indicates that the rocks equilibrated at 1050 ± 50 °C, which represents the high-temperature, low-pressure event that generated their characteristic recrystallization textures and reset their Ar systematics. Stepped-heating, in situ infrared laser microprobe 40 Ar– 39 Ar geochronology yields a mean age of 3327 ± 29 Ma for NWA 3163, and a more disturbed release spectrum for NWA 4881. NWA 4881 shows an upward-trending pattern, suggesting that it may have had a 40 Ar– 39 Ar age of >3.0 Ga, but that it was partially reset at ∼2.6 Ga. NWA 3163 et al. exhibit shock effects, including maskelynitized plagioclase, shock veins, and melt pockets, which are absent in the Apollo granulitic breccias. Although the Apollo and meteorite samples are texturally similar and have comparable bulk compositions and equilibration temperatures, their trace and siderophile element contents point to distinct parental lithologies derived from different regions of the Moon. Based on mineralogical and geochemical differences between the Apollo and meteorite samples, we conclude that the parent rock(s) of the paired NWA meteorites came from an area outside the Imbrium region and that they underwent high-temperature (granulite event) metamorphism long after the Late Heavy Bombardment.

Published

2011

32. Coesite and stishovite in a shocked lunar meteorite, Asuka-881757, and impact events in lunar surface

Author

Masaaki Miyahara, Y. Ito, Eiji Ohtani, Kazuhisa Sato, Takashi Mikouchi, Kenji Hiraga, Makoto Kimura, T. Arai, and Shin Ozawa

Subjects

Basalt, Lunar meteorite, Minerals, Time Factors, Multidisciplinary, Materials science, Surface Properties, Meteoroids, Quartz, engineering.material, Silicon Dioxide, Spectrum Analysis, Raman, Astrobiology, Microscopy, Electron, Transmission, Meteorite, Physical Sciences, Breccia, Coesite, Microscopy, Electron, Scanning, Pressure, engineering, Moon, Late Heavy Bombardment, Stishovite

Abstract

Microcrystals of coesite and stishovite were discovered as inclusions in amorphous silica grains in shocked melt pockets of a lunar meteorite Asuka-881757 by micro-Raman spectrometry, scanning electron microscopy, electron back-scatter diffraction, and transmission electron microscopy. These high-pressure polymorphs of SiO 2 in amorphous silica indicate that the meteorite experienced an equilibrium shock-pressure of at least 8–30 GPa. Secondary quartz grains are also observed in separate amorphous silica grains in the meteorite. The estimated age reported by the 39 Ar/ 40 Ar chronology indicates that the source basalt of this meteorite was impacted at 3,800 Ma ago, time of lunar cataclysm; i.e., the heavy bombardment in the lunar surface. Observation of coesite and stishovite formed in the lunar breccias suggests that high-pressure impact metamorphism and formation of high-pressure minerals are common phenomena in brecciated lunar surface altered by the heavy meteoritic bombardment.

Published

2010

33. Lunar meteorite regolith breccias: An in situ study of impact melt composition using LA-ICP-MS with implications for the composition of the lunar crust

Author

Anton T. Kearsley, Katherine H. Joy, Ian A. Crawford, and Sara S. Russell

Subjects

Basalt, Lunar meteorite, education.field_of_study, Population, Geochemistry, Regolith, Geophysics, Impact crater, Meteorite, Space and Planetary Science, Breccia, Mafic, education, Geology

Abstract

Dar al Gani (DaG) 400, Meteorite Hills (MET) 01210, Pecora Escarpment (PCA) 02007, and MacAlpine Hills (MAC) 88104/88105 are lunar regolith breccia meteorites that provide sampling of the lunar surface from regions of the Moon that were not visited by the US Apollo or Soviet Luna sample return missions. They contain a heterogeneous clast population from a range of typical lunar lithologies. DaG 400, PCA 02007, and MAC 88104/88105 are primarily feldspathic in nature, and MET 01210 is composed of mare basalt material mixed with a lesser amount of feldspathic material. Here we present a compositional study of the impact melt and impact melt breccia clast population (i.e., clasts that were generated in impact cratering melting processes) within these meteorites using in situ electron microprobe and LA-ICP-MS techniques. Results show that all of the meteorites are dominated by impact lithologies that are relatively ferroan (Mg# 10), and have low incompatible trace element (ITE) concentrations (i.e., typically 10 ppm Sm), High Magnesium Suite (typically >70 Mg#) or High Alkali Suite (high ITEs, Sc/Sm ratios

Published

2010

34. Antarctic lunar meteorites Yamato-793169, Asuka-881757, MIL 05035, and MET 01210 (YAMM): Launch pairing and possible cryptomare origin

Author

Keiji Misawa, Tomoko Arai, Thomas A. Giguere, Hideyasu Kojima, B. Ray Hawke, and Masamichi Miyamoto

Subjects

Lunar meteorite, Basalt, Impact crater, Meteorite, Geochemistry and Petrology, Breccia, Geochemistry, KREEP, Pyroxene, Regolith, Geology

Abstract

The Antarctic lunar meteorite Meteorite Hills (MET) 01210 is a polymict regolith breccia, dominantly composed of mare basalt components. One relatively large (2.7 × 4.7 mm) basalt clast in MET 01210 (MET basalt) shows remarkable mineralogical similarities to the lunar-meteorite crystalline mare basalts Yamato (Y)-793169, Asuka (A)-881757, and Miller Range (MIL) 05035. All four basalts have similar rock texture, mineral assemblage, mineral composition, pyroxene crystallization trend, and pyroxene exsolution lamellae. The estimated TiO 2 contents (∼2.0 wt%) of the MET basalt and MIL 05035 are close to the bulk-rock TiO 2 contents of Y-793169 and A-881757. These similarities suggest that Y-793169, A-881757, MIL 05035, and the MET basalt came from the same basalt flow, which we designate the YAMM basalt. The source-basalt pairing of the YAMM is also supported by their similar REE abundances, crystallization ages (approx. 3.8–3.9 Ga), and isotopic compositions (low U/Pb, low Rb/Sr, and high Sm/Nd). The pyroxene exsolution lamellae, which are unusually coarse (up to a few microns) by mare standards, imply a relatively slow cooling in an unusually thick lava and/or subsequent annealing within a cryptomare. Reported noble gas and CRE data with close launch ages (∼1 Ma) and ejection depths (deeper than several meters) among the four meteorites further indicate their simultaneous ejection from the moon. Despite the marginally close terrestrial ages, pairing in the conventional Earth-entry sense seems unlikely because of the remote recovery sites among the YAMM meteorites. The high abundance (68%) of mare components in MET 01210 estimated from a two-component mixing model calculation could have resulted from either lateral mixing at a mare-highland boundary or vertical mixing in a cryptomare. The proportion of mare materials in MET 01210 is greater than in Apollo core samples at the mare-highland boundary. The burial depth (>several meters deep) inferred from the lack of surface irradiation of MET 01210 exceeds the typical mare regolith thickness (a few meters). Thus, the source of the YAMM meteorites is likely a terrain of locally high mare-highland mixing within a cryptomare. We searched for a possible source crater of the YAMM meteorites within the well-defined cryptomare, based on the multiple constraints obtained from this study and published data. An unnamed 1.4 km-diameter crater (53°W, 44.5°S) on the floor of the Schickard crater is the most suitable source for the YAMM meteorites. The 238 U/ 204 Pb ( μ ) value of the YAMM basalts is extremely low, relative to those of the Apollo mare basalts, but comparable to those of the Luna 24 very low-Ti basalts. The low- μ source indicates a derivation from a less differentiated mantle with a lack of KREEP components. Although the chemical sources of materials and heat source of melting might be independent, the heat source that generated the source magma of the YAMM and Luna 24 basalts may not be related to KREEP, unlike the case of the Apollo basalts. The distinct chemical and isotopic compositions of mantle sources between the Apollo basalts and the YAMM/Lunar 24 basalts imply differences in mantle composition and thermal evolution between the Procellarum KREEP Terrane (PKT) and non-PKT regions of the nearside.

Published

2010

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

Author

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

Subjects

Lunar meteorite, Isochron, Basalt, Sensitive high-resolution ion microprobe, Geochemistry, engineering.material, Regolith, Geophysics, Meteorite, Space and Planetary Science, Geochemistry and Petrology, Breccia, Earth and Planetary Sciences (miscellaneous), engineering, Plagioclase, Geology

Abstract

ARTICLE I NFO 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 238 U/ 206 Pb- 207 Pb/ 206 Pb- 204 Pb/ 206 Pb 3-D space (95% confidence level). The observed Pb-Pb isochron of these eight phosphates coupled with four plagioclase grains alsoyieldeda 207 Pb/ 206 Pbageof3.35±0.13Ga.Thisformationage,whenconsideredasthecrystallizationageof

Published

2008

36. Osmium isotope and highly siderophile element systematics of lunar impact melt breccias: Implications for the late accretion history of the Moon and Earth

Author

David A. Kring, Richard J. Walker, O. B. James, and Igor S. Puchtel

Subjects

Lunar meteorite, Accretion (meteorology), Meteorite, Geochemistry and Petrology, Chondrite, Clastic rock, Breccia, Geochemistry, Poikilitic, Earth (classical element), Geology

Abstract

To characterize the compositions of materials accreted to the Earth–Moon system between about 4.5 and 3.8 Ga, we have determined Os isotopic compositions and some highly siderophile element (HSE: Re, Os, Ir, Ru, Pt, and Pd) abundances in 48 subsamples of six lunar breccias. These are: Apollo 17 poikilitic melt breccias 72395 and 76215; Apollo 17 aphanitic melt breccias 73215 and 73255; Apollo 14 polymict breccia 14321; and lunar meteorite NWA482, a crystallized impact melt. Plots of Ir versus other HSE define excellent linear correlations, indicating that all data sets likely represent dominantly two-component mixtures of a low-HSE target, presumably endogenous component, and a high-HSE, presumably exogenous component. Linear regressions of these trends yield intercepts that are statistically indistinguishable from zero for all HSE, except for Ru and Pd in two samples. The slopes of the linear regressions are insensitive to target rock contributions of Ru and Pd of the magnitude observed; thus, the trendline slopes approximate the elemental ratios present in the impactor components contributed to these rocks. The 187 Os/ 188 Os and regression-derived elemental ratios for the Apollo 17 aphanitic melt breccias and the lunar meteorite indicate that the impactor components in these samples have close affinities to chondritic meteorites. The HSE in the Apollo 17 aphanitic melt breccias, however, might partially or entirely reflect the HSE characteristics of HSE-rich granulitic breccia clasts that were incorporated in the impact melt at the time of its creation. In this case, the HSE characteristics of these rocks may reflect those of an impactor that predated the impact event that led to the creation of the melt breccias. The impactor components in the Apollo 17 poikilitic melt breccias and in the Apollo 14 breccia have higher 187 Os/ 188 Os, Pt/Ir, and Ru/Ir and lower Os/Ir than most chondrites. These compositions suggest that the impactors they represent were chemically distinct from known chondrite types, and possibly represent a type of primitive material not currently delivered to Earth as meteorites.

Published

2008

37. Mineralogy, petrology, and shock history of lunar meteorite Sayh al Uhaymir 300: A crystalline impact-melt breccia

Author

John G. Spray, Jillian A. Hudgins, and Erin L. Walton

Subjects

Lunar meteorite, Meteorite classification, Geochemistry, Maskelynite, engineering.material, Breakup, Grain size, Igneous rock, Geophysics, Geology of the Moon, Space and Planetary Science, Breccia, engineering, Petrology, Geology

Abstract

Sayh al Uhaymir (SaU) 300 comprises a microcrystalline igneous matrix (grain size S4). The association of maskelynite with melt pockets and shock veins indicates a subsequent, local 28-45 GPa (shock stage S2-S3) excursion, which was probably responsible for lofting the sample from the lunar surface. Subsequent fracturing is attributed to atmospheric entry and probable breakup of the parent meteor.

Published

2007

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

Author

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

Subjects

Lunar meteorite, Isochron, Basalt, Geochemistry, Regolith, Geophysics, Meteorite, Space and Planetary Science, Geochemistry and Petrology, Clastic rock, Breccia, Earth and Planetary Sciences (miscellaneous), Radiometric dating, Geology

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.

Published

2007

39. Comment on: 'New' lunar meteorites: Impact melt and regolith breccias and large-scale heterogeneities of the upper lunar crust, by P. H. Warren, F. Ulff-Møller, and G. W. Kallemeyn

Author

O. B. James, Lawrence A. Taylor, Barbara A. Cohen, and Mikhail A. Nazarov

Subjects

Lunar meteorite, Lithology, Geochemistry, Maskelynite, engineering.material, Texture (geology), Regolith, Geophysics, Meteorite, Space and Planetary Science, Breccia, engineering, Mafic, Geology

Abstract

We described lunar meteorite Dhofar 026 (Cohen et al. 2004) and interpreted this rock as a strongly shocked granulitic breccia (or fragmental breccia consisting almost entirely of granuliticbreccia clasts) that was partially melted by post-shock heating. Warren et al. (2005) objected to many aspects of our interpretation: they were uncertain whether or not the bulk rock had been shocked; they disputed our identification of the precursor as granulitic breccia; and they suggested that mafic, igneous-textured globules within the breccia, which we proposed were melted by post-shock heating, are clasts with relict textures. The major evidence for shock of the bulk rock is the fact that the plagioclase in the lithologic domains that make up 80-90% of the rock is devitrified maskelynite. The major evidence for a granulitic-breccia precursor is the texture of the olivine-plagioclase domain that constitutes 40-45% of the rock; Warren et al. apparently overlooked or ignored this lithology. Textures of the mafic, igneous-textured globules, and especially of the vesicles they contain, demonstrate that these bodies were melted and crystallized in situ. Warren et al. suggested that the rock might have originally been a regolith breccia, but the textural homogeneity of the rock and the absence of solar windderived noble gases preclude a regolith-breccia precursor. Warren et al. classified the rock as an impact-melt breccia, but they did not identify any fraction that was impact melt.

Published

2007

40. Vertical compositional variation of lunar mare basalts inferred from mineralogy and spectroscopy of basaltic breccias

Author

Arai, Tomoko, Otake, Makiko, and Nimura, Tokuhiro

Subjects

basalt, reflectance spectrum, lunar meteorite, 月隕石, 月探査, 反射スペクトル, lunar surface, 結晶学, 月面, 鉱物学, lunar exploration, 化学組成, chemical composition, mineralogy, 玄武岩, crystallography, 角礫岩, breccia

Abstract

Recent mineralogical studies of lunar mare meteorites have revealed that most crystalline basalts (i.e. Apollo samples) do not represent primary magma compositions but only represent Fe-rich upper layer of the basalt flow. In contrast, basaltic breccias tend to represent the average (approximately true) basalt composition because they consist of mixtures of Mg-rich lower layer and Fe-rich upper layer of the basalt flow. Thus, basaltic breccias are more suitable to estimate the true basalt composition. The thickness of the basalt included in lunar meteorite MET 01210 is estimated to be 50-100 m. Spectral analysis of a Mg-rich basalt breccia and an Fe-rich crystalline basalt shows that they can be spectroscopically distinguished by lateral shift of reflectance spectra and the associated individual absorption bands. This indicates that the SELENE (SELenological and ENgineering Explorer) multispectral data with high spatial resolution can be utilized to understand vertical compositional variation within a basalt unit and estimate the true basalt composition., 資料番号: AA0063505025

Published

2006

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

Author

Yuzuru Karouji, Kazuto Saiki, Mitsuru Ebihara, Hiroshi Takeda, Tomoko Arai, Donald D. Bogard, Akira Yamaguchi, and Makiko Ohtake

Subjects

Lunar meteorite, Olivine, Geochemistry, Crust, Pyroxene, engineering.material, Anorthosite, Geophysics, Meteorite, Space and Planetary Science, Geochemistry and Petrology, Clastic rock, Breccia, Earth and Planetary Sciences (miscellaneous), engineering, Geology

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.

Published

2006

42. Lunar highland meteorite Dhofar 026 and Apollo sample 15418: Two strongly shocked, partially melted, granulitic breccias

Author

Mikhail A. Nazarov, O. B. James, Larisa D. Barsukova, Barbara A. Cohen, and Lawrence A. Taylor

Subjects

Lunar meteorite, Partial melting, Geochemistry, Maskelynite, Pyroxene, engineering.material, Petrography, Geophysics, Meteorite, Space and Planetary Science, Breccia, engineering, Plagioclase, Geology

Abstract

Studies of lunar meteorite Dhofar 026, and comparison to Apollo sample 15418, indicate that Dhofar 026 is a strongly shocked granulitic breccia (or a fragmental breccia consisting almost entirely of granulitic breccia clasts) that experienced considerable post-shock heating, probably as a result of diffusion of heat into the rock from an external, hotter source. The shock converted plagioclase to maskelynite, indicating that the shock pressure was between 30 and 45 GPa. The post-shock heating raised the rock's temperature to about 1200 °C; as a result, the maskelynite devitrified, and extensive partial melting took place. The melting was concentrated in pyroxene-rich areas; all pyroxene melted. As the rock cooled, the partial melts crystallized with fine-grained, subophitic-poikilitic textures. Sample 15418 is a strongly shocked granulitic breccia that had a similar history, but evidence for this history is better preserved than in Dhofar 026. The fact that Dhofar 026 was previously interpreted as an impact melt breccia underscores the importance of detailed petrographic study in interpretation of lunar rocks that have complex textures. The name "impact melt" has, in past studies, been applied only to rocks in which the melt fraction formed by shock-induced total fusion. Recently, however, this name has also been applied to rocks containing melt formed by heating of the rocks by conductive heat transfer, assuming that impact is the ultimate source of the heat. We urge that the name "impact melt" be restricted to rocks in which the bulk of the melt formed by shock-induced fusion to avoid confusion engendered by applying the same name to rocks melted by different processes.

Published

2004

43. Petrogenesis of lunar highlands meteorites: Dhofar 025, Dhofar 081, Dar al Gani 262, and Dar al Gani 400

Author

Barbara A. Cohen, Christine Floss, Mikhail A. Nazarov, Lawrence A. Taylor, Mahesh Anand, and Joshua T.S. Cahill

Subjects

Lunar meteorite, Geochemistry, engineering.material, Anorthosite, Geophysics, Geology of the Moon, Meteorite, Space and Planetary Science, Breccia, engineering, Plagioclase, Mafic, Geology, Petrogenesis

Abstract

The petrogenesis of four lunar highlands meteorites, Dhofar 025 (Dho 025), Dhofar 081 (Dho 081), Dar al Gani 262 (DaG 262), and Dar al Gani 400 (DaG 400) were studied. For Dho 025, measured oxygen isotopic values and Fe-Mn ratios for mafic minerals provide corroboratory evidence that it originated on the Moon. Similarly, Fe-Mn ratios in the mafic minerals of Dho 081 indicate lunar origin. Lithologies in Dho 025 and Dho 081 include lithic clasts, granulites, and mineral fragments. A large number of lithic clasts have plagioclase AN# and coexisting mafic mineral Mg# that plot within the "gap" separating ferroan anorthosite suite (FAN) and high-magnesium suite (HMS) rocks. This is consistent with whole rock Ti-Sm ratios for Dho 025, Dho 081, and DaG 262, which are also intermediate compared to FAN and HMS lithologies. Although ion microprobe analyses performed on Dho 025, Dho 081, DaG 262, and DaG 400 clasts and minerals show far stronger FAN affinities than whole rock data suggest, most clasts indicate admixture of ≤12% HMS component based on geochemical modeling. In addition, coexisting plagioclase-pyroxene REE concentration ratios in several clasts were compared to experimentally determined plagioclase-pyroxene REE distribution coefficient ratios. Two Dho 025 clasts have concordant plagioclase-pyroxene profiles, indicating that equilibrium between these minerals has been sustained despite shock metamorphism. One clast has an intermediate FAN-HMS composition. These lunar meteorites appear to represent a type of highland terrain that differs substantially from the KREEP-signatured impact breccias that dominate the lunar database. From remote sensing data, it is inferred that the lunar far side appears to have appropriate geochemical signatures and lithologies to be the source regions for these rocks; although, the near side cannot be completely excluded as a possibility. If these rocks are, indeed, from the far side, their geochemical characteristics may have far-reaching implications for our current scientific understanding of the Moon.

Published

2004

44. Feldspathic lunar meteorites and their implications for compositional remote sensing of the lunar surface and the composition of the lunar crust

Author

Larry A. Haskin, Randy L. Korotev, Ryan A. Zeigler, Jeffrey J. Gillis, and Bradley L. Jolliff

Subjects

Lunar meteorite, Anorthosite, Incompatible element, Meteorite, Lunar magma ocean, Geochemistry and Petrology, Breccia, engineering, Geochemistry, Plagioclase, Crust, engineering.material, Geology

Abstract

We present new compositional data for six feldspathic lunar meteorites, two from cold deserts (Yamato 791197 and 82192) and four from hot deserts (Dhofar 025, Northwest Africa 482, and Dar al Gani 262 and 400). The concentrations of FeO (or Al2O3) and Th (or any other incompatible element) together provide first-order compositional information about lunar polymict samples (breccias and regoliths) and regions of the lunar surface observed from orbit. Concentrations of both elements on the lunar surface have been determined from data acquired by orbiting spacecraft, although the derived concentrations have large uncertainties and some systematic errors compared to sample data. Within the uncertainties and errors in the concentrations derived from orbital data, the distribution of FeO and Th concentrations among lunar meteorites, which represent ∼18 source regions on the lunar surface, is consistent with that of 18 random samples from the surface. Approximately 11 of the lunar meteorites are low-FeO and low-Th breccias, consistent with large regions of the lunar surface, particularly the northern farside highlands. Almost all regoliths from Apollo sites, on the other hand, have larger concentrations of both elements because they contain Fe-rich volcanic lithologies from the nearside maria and Th-rich lithologies from the high-Th anomaly in the northwestern nearside. The feldspathic lunar meteorites thus offer our best estimate of the composition of the surface of the feldspathic highlands, and we provide such an estimate based on the eight most well-characterized feldspathic lunar meteorites. The variable but high (on average) Mg/Fe ratio of the feldspathic lunar meteorites compared to ferroan anorthosites confirms a hypothesis that much of the plagioclase at the surface of the feldspathic highlands is associated with high-Mg/Fe feldspathic rocks such as magnesian granulitic breccia, not ferroan anorthosite. Geochemically, the high-Mg/Fe breccias appear to be unrelated to the mafic magnesian-suite rocks of the Apollo collection. Models for the formation of the upper lunar crust as a simple flotation cumulate composed mainly of ferroan anorthosite do not account for the complexity of the crust as inferred from the feldspathic lunar meteorites.

Published

2003

45. Petrogenesis of lunar meteorite EET 96008

Author

Kentaro Terada, Allan Patchen, Yuji Sano, Clive R. Neal, Mahesh Anand, Lawrence A. Taylor, and Gregory A. Snyder

Subjects

Isochron, Basalt, Lunar meteorite, Fractional crystallization (geology), Lithic fragment, Meteorite, Geochemistry and Petrology, Breccia, Geochemistry, Geology, Petrogenesis

Abstract

Lunar meteorite EET 96008 is a fragmental breccia that predominantly consists of basaltic mineral clasts (0.5–2 mm), along with minor lithic fragments and breccia clasts. The matrix consists mainly of smaller mineral fragments ( The molar Fe/Mn ratio in olivines and pyroxenes and the age of the meteorite are evidence for a lunar origin. The mineralogy of EET 96008 shows close affinity to a mare-basalt source, albeit with possible minor highland/non-mare components. The bulk-rock, major-, trace- and rare-earth-element (REE) contents are similar to that of very low-titanium (VLT) basalts, which have experienced extreme fractional crystallization to the point of silicate liquid immiscibility. Mineralogical and textural features of this sample suggest that at least some of the breccia components were derived from a slow-cooled magma. The mineralogy and petrology of EET 96008 is strikingly similar to the lunar meteorite EET 87521, and we support the conclusion that EET 96008 and EET 87521 should be paired. Isochron ages of 3530 ± 270 Ma for apatite and 3519 ± 100 Ma for whitlockite of this rock are consistent with derivation from a mare-basalt precursor. These ages are within error of the low-Ti basalts, dated from the Apollo 12 and 15 sites. The whole-rock, platinum-group-element (PGE) contents of EET 96008 overlap with pristine low-Ti mare basalts, suggesting the presence of only a minimal extraterrestrial component.

Published

2003

46. 40Ar-39Ar chronology of lunar meteorites Northwest Africa 032 and 773

Author

Vera A. Fernandes, Grenville Turner, and Ray Burgess

Subjects

Basalt, Lunar meteorite, Lunar mare, Geochemistry, Pyroxene, engineering.material, Feldspar, Geophysics, Meteorite, Space and Planetary Science, visual_art, Breccia, engineering, visual_art.visual_art_medium, Plagioclase, Geology

Abstract

The 40Ar-39Ar dating technique has been applied to the lunar meteorites Northwest Africa 032 (NWA 032), an unbrecciated mare basalt, and Northwest Africa 773 (NWA 773), (composed of cumulate and breccia lithologies), to determine the crystallization age and timing of shock events these meteorites may have experienced. Stepped heating analyses of several different samples of NWA 032 gave complex age spectra but indistinguishable total ages with a mean of 2.779 ± 0.014 Gyr. Possible causes of the complex age spectra obtained from NWA 032 include recoil of 39Ar, or the presence of pre-shock 40Ar incorporated into shock-melt veins. The effects of shock veins were investigated by laser fusion of 20 small samples expected to contain varying proportions of the shock veins. The laser ages show a narrow age distribution between 2.61-­2.86 Gyr and a mean of 2.73 ± 0.03 Gyr, identical to the total age of ~2.80 Gyr obtained for the bulk sample. Diffusion calculations based on the stepped heating data indicate that Ar release can be reconciled by release from feldspar (and possibly shock veins) at low temperatures followed by pyroxene at higher temperatures. The exposure age of NWA 032 is 212 ± 11 Myr, and it contains low trapped solar Ar. Stepped heating of cumulate and breccia portions of NWA 773 also give a relatively young age of 2.91 Gyr. The presence of trapped Ar in the breccia makes the age determination of this component less precise, but release of Ar appears to be from the same mineral phase, assumed to be plagioclase, in both lithologies. A marked difference in exposure age between the 2 lithologies also exists, with the breccia having spent 81 Myr longer at the lunar surface; this finding is consistent with the higher trapped Ar content of this lithology. Assuming that 2.80 Gyr and 2.91 Gyr are the crystallization ages of NWA 032 and NWA 773 respectively, these two meteorites are the youngest lunar mare basalts available for study.

Published

2003

47. An unusual clast in lunar meteorite MacAlpine Hills 88105: A unique lunar sample or projectile debris?

Author

Gary R. Huss, G. J. Taylor, Kazuhide Nagashima, Katherine H. Joy, and Ian A. Crawford

Subjects

Lunar meteorite, Olivine, Geochemistry, Pyroxene, engineering.material, Regolith, Geophysics, Meteorite, Geology of the Moon, Space and Planetary Science, Breccia, engineering, cps, Plagioclase, Geology

Abstract

Lunar meteorite MacAlpine Hills (MAC) 88105 is a well-studied feldspathic regolith breccia dominated by rock and mineral fragments from the lunar highlands. Thin section MAC 88105,159 contains a small rock fragment, 400 × 350 μm in size, which is compositionally anomalous compared with other MAC 88105 lithic components. The clast is composed of olivine and plagioclase with minor pyroxene and interstitial devitrified glass component. It is magnesian, akin to samples in the lunar High Mg-Suite, and also alkali-rich, akin to samples in the lunar High Alkali Suite. It could represent a small fragment of late-stage interstitial melt from an Mg-Suite parent lithology. However, olivine and pyroxene in the clast have Fe/Mn ratios and minor element concentrations that are different from known types of lunar lithologies. As Fe/Mn ratios are notably indicative of planetary origin, the clast could either (1) have a unique lunar magmatic source, or (2) have a nonlunar origin (i.e., consist of achondritic meteorite debris that survived delivery to the lunar surface). Both hypotheses are considered and discussed. © The Meteoritical Society, 2014.

Published

2014

48. Dhofar 081: A new lunar highland meteorite

Author

Ludolf Schultz, Dieter Stöffler, R. T. Schmitt, M. Pätsch, and Ansgar Greshake

Subjects

Lunar meteorite, Recrystallization (geology), Olivine, Geochemistry, Pyroxene, engineering.material, Geophysics, Meteorite, Space and Planetary Science, Breccia, engineering, Plagioclase, Mafic, Geology

Abstract

— The lunar meteorite Dhofar 081, found as a single fragment of 174 g in the Dhofar region of Oman, is a shocked feldspathic fragmental highland breccia dominated by anorthosite-rich lithic and mineral clasts embedded into a fine-grained mostly shock melted clastic matrix. Major mineral phases in the bulk rock are Ca-rich plagioclase (An96.5–99.5), pyroxene (FS21.9–46.2Wo3.0–41.4), and olivine (Fa29.3–47.8); accessory phases include Fe-Ni metal, ilmenite, and Ti-Cr-rich spinel. Dhofar 081 contains subordinate crystalline fragments of large anorthosites, intersertal impact-melt rocks, microporphyritic impact-melt breccias, dark fine-grained impact-melt breccias, large cataclastic feldspars, and irregularly shaped brown glass clasts. Mafic components are rare and no genuine regolith components were found in the sections studied. Minerals in Dhofar 081 show homogeneously distributed shock features: intergranular recrystallization, strong fracturing and mosaicism in feldspar as well as a high density of mostly irregular fractures in pyroxene and olivine. Localized impact melting caused by one or several impacts led to a strong lithification. Based on these effects an equilibration shock pressure of about 15–20 GPa is estimated for the strongest shock event in Dhofar 081. Devitrification of the “glassy” material in the rock indicates thermal annealing after shock melting suggesting that the 15–20 GPa shock event predated the ejection event. According to the concentrations of implanted solar noble gases Dhofar 081 represents a polymict clastic breccia deposit with possibly a minor regolith component. A similar noble gas record of Dhofar 081 and MacAlpine Hills 88104/05 suggests the possibility of a source crater pairing of both meteorites. As indicated by noble gas measurements pairing of Dhofar 081 with the other lunar meteorites found in Oman, Dhofar 025 and Dhofar 026, is unlikely.

Published

2001

49. Lunar meteorite Queen Alexandra Range 94281: Glass compositions and other evidence for launch pairing with Yamato 793274

Author

Paul H. Warren and Tomoko Arai

Subjects

Basalt, Lunar meteorite, geography, geography.geographical_feature_category, Geochemistry, Pyroclastic rock, Pyroxene, Regolith, Volcanic rock, Geophysics, Meteorite, Space and Planetary Science, Breccia, Geology

Abstract

— Lunar meteorite Queen Alexandra Range 94281 is remarkably similar to Yamato 793274. Pairing in the conventional Earth-entry sense is difficult to reconcile with the 2500 km separation between the find locations for these two samples. Nonetheless, both of these regolith breccias are dominated by very-low-Ti (VLT) mare basalt, the pyroxenes of which feature exsolution lamellae on a remarkably coarse scale (typical lamella width = 0.5–1 μm) by mare standards. The pyroxenes also show similar compositional variations (e.g., Fe# vs. Ti# trends, which confirm parentage from VLT mare basalt). Plots using Al2O3 or FeO as a tracer of the highland component indicate indistinguishable internal mare-highland geochemical mixing trends. The same two distinctive glass types dominate the mare glass populations of both breccias. Glass type YQ1 features 0.37–0.63 wt% TiO2, 10–17 wt% MgO, and 9–11 wt% Al2O3. Glass type YQ2 features higher TiO2 (0.99–1.22 wt%), which is inversely correlated with MgO (12.6–13.8 wt%), and nearly constant (8.8 wt%) Al2O3. All of these similarities suggest that Y-793274 and QUE 94281 are a launch pair, which we designate YQ. Most of these similarities also extend to another mare-breccia meteorite, Elephant Moraine 87521. However, the EET 87521 mare basalt is unusually V-poor (∼88 μg/g), whereas the YQ mare component contains ∼166 μg/g. Queen Alexandra Range 94281 features a variety of textural domains. Discrete patches of dark matrix material appear to represent clods of mature regolith that have been mixed with a coarser, relatively immature material. Interior to a frothy fusion crust are areas of massive glass that probably formed as a splash coating on QUE 94281 when it was still on the Moon. The coarse YQ and EET 87521 pyroxene exsolution features imply relatively slow cooling in either a very shallow sill or an unusually thick (ponded) lava and/or later annealing within a cryptomare. Mare pyroclastic glasses, including the two YQ varieties, are systematically MgO-rich compared to crystalline mare basalts. This disparity may be a consequence of limited survival of graphite—the main fuel for explosive volcanism—during formation of the mare source regions as magma ocean cumulates. Graphite (2.2 g/cm3) survived preferentially in regions that avoided extensive early melting and thus remained MgO-rich. An apparent bimodality in the TiO2 contents of mare volcanics, especially the pyroclastic glasses, also seems a plausible consequence of petrogenesis by remelting of magma ocean cumulates. Cumulates deposited after the magma ocean evolved to ilmenite saturation had vastly higher TiO2 contents than cumulates deposited shortly before. The YQ regolith's subequal proportions of mare and highland matter are consistent with derivation from a terrain close to a mare-highland boundary. However, a similar mixture might also develop through vertical mixing in a cryptomare or a region of thin mare coverage. Thus, unfortunately, the YQ bulk composition is not a very useful clue to the identity of the source crater.

Published

1999

50. Petrology, chemistry, and isotopic compositions of the lunar highland regolith breccia Dar al Gani 262

Author

U. Herpers, Addi Bischoff, D. Wolf, P. W. Kubik, S. Neumann, Ludolf Schultz, Ian A. Franchi, Robert N. Clayton, A. B. Verchovsky, Herbert Palme, Thomas Faestermann, Gunther Korschinek, B. Spettel, A. S. Sexton, C. T. Pillinger, Klaus Knie, Toshiko K. Mayeda, Silke Merchel, Rolf Michel, D. Weber, G. Weckwerth, and H. W. Weber

Subjects

Petrography, Lunar meteorite, Geophysics, Space and Planetary Science, Thin section, Clastic rock, Breccia, Geochemistry, Mineralogy, Mafic, Chemical composition, Regolith, Geology

Abstract

— Lunar meteorite Dar al Gani 262 (DG 262)—found in the Libyan part of the Sahara—is a mature, anorthositic regolith breccia with highland affinities. The origin from the Moon is undoubtedly indicated by its bulk chemical composition; radionuclide concentrations; noble gas, N, and O isotopic compositions; and petrographic features. Dar al Gani 262 is a typical anorthositic highland breccia similar in mineralogy and chemical composition to Queen Alexandra Range (QUE) 93069. About 52 vol% of the studied thin sections of Dar al Gani 262 consist of fine-grained(100 μm) constituents, and 48 vol% is mineral and lithic clasts and impact-melt veins. The most abundant clast types are feldspathic fine-grained to microporphyritic crystalline melt breccias (50.2 vol%; includes recrystallized melt breccias), whereas mafic crystalline melt breccias are extremely rare (1.4 vol%). Granulitic lithologies are 12.8 vol%, intragranularly recrystallized anorthosites and cataclastic anorthosites are 8.8 and 8.2 vol%, respectively, and (devitrified) glasses are 2.7 vol%. Impact-melt veins (5.5 vol% of the whole thin sections) cutting across the entire thin section were probably formed subsequent to the lithification process of the bulk rock at pressures below 20 GPa, because the bulk rock never experienced a higher peak shock pressure. Mafic crystalline melt breccias are very rare in Dar al Gani 262 and are similar in abundance to those in QUE 93069. The extremely low abundance of mafic components and the bulk composition may constrain possible areas of the Moon from which the breccia was derived. The source area of Dar al Gani 262 must be a highland terrain lacking significant mafic impact melts or mare components. On the basis of radionuclide activities, an irradiation position of DG 262 on the Moon at a depth of 55–85 g/cm3and a maximum transit time to Earth

Published

1998