Your search keyword '"meteorites"' showing total 17,304 results

1. METEOR WATCH

Subjects

Meteorites, Astronomy

Abstract

Fighting moonlight THE REMNANTS OF HALLEY'S COMET generate the annual meteor shower called the Orionids. It's active from Oct. 2 through Nov. 7, with the peak occurring on Oct. 21. [...]

Published

2024

2. A petrogenetic study of apatite in Chang'E-5 basalt: Implications for high sulfur contents in lunar apatite and volatile estimations for the lunar mantle.

Author

Li, Huijuan, Wang, Zilong, Chen, Zhenyu, Tian, Wei, Wang, Wei-(RZ), Zhang, Guibin, and Zhang, Lifei

Subjects

*EARTH'S mantle, *APATITE, *BASALT, *METEORITES, *PETROGENESIS

Abstract

Apatite is ubiquitous in lunar samples and has been used widely for estimating volatile abundances in the lunar interior. However, apatite compositional and isotopic variations within and between samples have resulted in varying and ambiguous results. Understanding apatite petrogenesis will help with both identifying the appropriate composition for volatile estimation and interpreting isotopic variations. Here we report a comprehensive petrogenetic investigation of apatite in Chang'E-5 (CE5) basaltic sample CE5C0800YJYX013GP. Apatite displays both intra-grain and inter-grain compositional variations with F and Cl contents falling in the ranges of 0.97–2.47 wt% and 0.24–1.09 wt%, respectively. These apatite compositions show relatively low F and high Cl characteristics in comparison to apatites of Apollo high-Ti and low-Ti mare basalts, but are similar to those reported for lunar meteorites LAP 04841 and MIL 05035. We discern three zoning profiles: fractional crystallization (FC)-dominated, degassing-induced and a third indicated by REE-enriched cores, which are interpreted as representing different generations of apatite. FC-dominated zoning is characterized with decreasing F and increasing Cl and S contents from core to rim; while the opposite is true for the degassing-induced zoning. Regardless of the zoning patterns, apatite Cl and S contents display positive correlations, with S contents up to ∼ 3000 ppm, much higher than previous reports for Apollo samples (up to ∼ 600 ppm). We demonstrate that the fractional crystallization model proposed by Boyce et al. (2014) in combination with H 2 O degassing and high S contents in melt (likely at sulfide saturation) can explain these high Cl and S contents observed in CE5 apatite. Based on the core composition of the FC-dominated zoning profile, which has the lowest incompatible element concentrations, bulk F, Cl and H 2 O contents in the parental melt are estimated to be ∼ 72 ± 21, ∼43 ± 14 and ∼ 1576 ± 518 ppm, respectively. These estimates have lower F/Cl ratios than those measured in olivine-hosted melt inclusions from Apollo mare basalts. By adopting the petrogenetic model for CE5 basalt proposed by Su et al. (2022) , i.e., 10 % partial melting of a hybrid mantle source, followed by ∼ 30–70 % fractional crystallization (∼50 % for our sample), we estimate the F, Cl, H 2 O and S contents in the mantle source are in the ranges of ∼ 2.5–4.6, ∼0.7–1.4, ∼53–105 and ∼ 38–125 ppm, respectively, similar to estimates for both depleted Earth mantle and primitive lunar mantle. However, by adopting the model of Tian et al. (2021) , 2–3 % partial melting of a mantle source composed of 86 PCS+2% TIRL (PCS, percent crystallized solid; TIRL, trapped instantaneous residual liquid), followed by 43–88 % fractional crystallization, these estimates will be 5–10 times lower. To be certain whether the relatively low F and high Cl characteristics of CE5 apatite imply an enriched mantle source requires further evaluation of the petrogenetic models for CE5 basalt. [ABSTRACT FROM AUTHOR]

Published

2024

3. Looking Back on the Rochester Mineralogical Symposium (1974-2023).

Author

Chamberlain, Steven C. and McDougall, Raymond

Subjects

*INTERNAL structure of the Earth, *MINERALS, *GEMS & precious stones, *PHOSPHATE minerals, *APATITE, *PYRITES, *GEOLOGY, *METEORITES, WESTERN United States history

Abstract

The Rochester Mineralogical Symposium (RMS) was a prominent event in specimen mineralogy for over five decades, featuring talks, technical sessions, publications, exhibits, and auctions that advanced the field. The symposium aimed to bring together collectors, curators, dealers, and professionals to share knowledge and promote mineral conservation and education. In 2011, the RMS was honored with the Carnegie Mineralogical Award for its significant contributions to mineralogy, preservation, conservation, and education. The legacy of the RMS endures through the relationships and collaborations it cultivated within the mineral community. [Extracted from the article]

Published

2024

4. Complex irradiation history of chondrules and matrix – A study of CR2 and some other meteorites.

Author

Beyersdorf-Kuis, Uta, Ott, Ulrich, and Trieloff, Mario

Subjects

*GALACTIC cosmic rays, *COSMIC rays, *CHONDRULES, *METEORITES, *NOBLE gases

Abstract

Excesses of cosmic-ray produced nuclei in individual components of meteorites indicate "pre-irradiation", either in the surface region of their parent bodies or as free-floating small particles in the early Solar System. We expand on our earlier work (Beyersdorf-Kuis et al., 2015) and report a study of cosmic-ray produced He and Ne in chondrules and "matrix" (i.e., matrix-dominated) material of several CR2 and CV meteorites as well as the highly primitive, unique, carbonaceous chondrite Acfer 094. In accordance with previous work, no evidence for pre-irradiation was found for CV3 Allende, while for CV3 Vigarano evidence for pre-irradiation is marginal at best. Also, the single chondrule from unique Acfer 094 that we studied has a cosmic ray exposure indistinguishable from the one we found for "matrix" material. Chondrules from Acfer 082 (CV) exhibit both excesses and deficits relative to "matrix", which points to pre-irradiation of not only chondrules, but also matrix material. A similar case may be Renazzo (CR2), where, however, the identification is complicated by the presence of abundant pre-solar Ne-E. A large number of chondrules (ten) were studied from CR2 El Djouf 001, which yielded slightly variable, small but consistent, excesses relative to "matrix", corresponding to "nominal" (i.e., irradiation by galactic cosmic rays in 4π geometry) excess ages of 1–2 Ma. Modelling suggests contributions from irradiation in the parent body regolith by solar cosmic rays (SCR) as well as galactic cosmic rays (GCR), where the latter dominates. Reevaluating the large variations previously identified in chondrules from QUE 99177, we suggest either a very different regolith history compared to that of El Djouf 001 or, more likely, pre-irradiation by, primarily, GCR in the early solar system as suggested previously. The case of solar-wind-rich NWA 852 (CR2) shows similarity to El Djouf 001 except for a much larger size of the effects. We suggest that the situation may be common among meteorites with a regolith origin. With independent information on the cosmic ray exposure age, which could be obtained by the study of cosmic-ray produced radionuclides, the individual parent body contributions may be disentangled, providing constraints on regolith dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

5. Curation and classification procedures for the UK Antarctic meteorite collection.

Author

MacArthur, J. L., Joy, K. H., Jones, R. H., Harvey, T. A., and Almeida, N. V.

Subjects

*ICE fields, *METEORITES, *BEST practices, *CLASSIFICATION, *COSMIC dust, ANTARCTIC exploration

Abstract

The field of advanced curation is important for existing astromaterials collections, which includes samples returned by space missions, and meteorites and cosmic dust samples that have been recovered from here on Earth. In order to maximize the scientific return of the samples, contamination needs to be minimized at all stages of sample collection, preliminary examination, classification, and curation. Utilizing best practice methods, a detailed acquisition and curation plan was implemented during the UK's first two expeditions to collect Antarctic meteorites from two new blue icefields, Hutchison Icefields and Outer Recovery Icefields. This article documents the design and execution of the procedures used during the project's curation and classification processes. It describes two case studies showing the processes applied to the recovered meteorites, and reviews our experiences and lessons learned for the future. [ABSTRACT FROM AUTHOR]

Published

2024

6. Raman Spectroscopy Investigations of Ribbeck Meteorite.

Author

Dudek, Mariusz, Grabarczyk, Jacek, Jakubowski, Tomasz, Zaręba, Paweł, and Karczemska, Anna

Subjects

*RAMAN spectroscopy, *PETROLOGY, *ORTHOPYROXENE, *SPECTRUM analysis, *METEORITES, *OLIVINE

Abstract

On 21 January 2024, asteroid 2024BX1, discovered the three hours before, fell to Earth south of Ribbeck in the Havelland region of Germany. In this study, fragments of the Ribbeck meteorite, characterized by white and gray colors lithology, were examined for their chemical and phase compositions. The white lithology fragment exhibited a homogeneous chemical and phase structure typical of orthopyroxene, which crystallizes in the orthorhombic system. The gray lithology fragment showed a greater diversity in chemical and phase compositions. Raman spectra analysis revealed that, in addition to the pyroxenes found in the white lithology fragment, minerals from the olivine group (fayalite and forsterite) were also present, along with plagioclase and sulfur in pure crystalline form. [ABSTRACT FROM AUTHOR]

Published

2024

7. Primitive asteroids as a major source of terrestrial volatiles.

Author

Martins, Rayssa, Morton, Elin M., Kuthning, Sven, Goes, Saskia, Williams, Helen M., and Rehkämper, Mark

Subjects

*INNER planets, *SOLAR system, *ISOTOPIC signatures, *METEORITES, *EARTH (Planet)

Abstract

The origins of Earth's volatiles are debated. Recent studies showed that meteorites display unique mass-independent isotopic signatures of the volatile element Zn, suggesting that Earth's Zn originated from materials derived from different regions of the Solar System. However, these studies largely omitted meteorites from the differentiated planetesimals thought to represent the Earth's building blocks, which underwent melting and substantial volatile loss. Here, we characterize the mass-independent Zn isotope compositions of meteorites from such planetesimals. We incorporate these results in mixing models that aim to reproduce Earth's abundance and isotope compositions of Zn and other elements. Our results suggest that, while differentiated planetesimals supplied ~70% of Earth's mass, they provided only ~10% of its Zn. The remaining Zn was supplied by primitive materials that did not experience melting and associated volatile loss. Combined with other findings, our results imply that an unmelted primitive material is likely required to establish the volatile budgets of the terrestrial planets. [ABSTRACT FROM AUTHOR]

Published

2024

8. Quasicrystal synthesis by shock compression.

Author

Hu, Jinping, Asimow, Paul D., Ma, Chi, Steinhardt, Paul J., and Bindi, Luca

Subjects

*QUASICRYSTALS, *DISCONTINUOUS precipitation, *SHEARING force, *METEORITES, *HIGH temperatures

Abstract

Quasicrystals are of interest because of their unique nonperiodic structures and physical properties. Motivated by naturally occurring icosahedral AlCuFe- and decagonal AlNiFe-phases hosted in a shocked meteorite, different laboratories have undertaken a series of shock recovery experiments to understand their formation mechanism. Shock experiments generate a complex series of processes and conditions, including a near-instantaneous excursion to high pressure and high temperature, large shear stresses, local melting, rapid decompression, fast quenching and post-shock annealing. This highly dynamic scenario offers a very useful but imperfect tool for exploring the stability of novel alloys, such as quasicrystals. So far, all the shock-synthesized quasicrystals differ considerably in composition from any thermodynamically stable or metastable quasicrystals synthesized by metallurgical techniques at low pressure, leaving plenty of questions to be answered about their formation conditions and their nucleation and growth mechanisms occurring during shock experiments. In this Perspective, we summarize the previous studies of shock-synthesized quasicrystals and discuss the advantages and difficulties caused by the experimental complexity. We also propose a few directions for future experiments to better control the shock conditions and understand the properties of quasicrystals. Shock compression is a highly dynamic, useful tool for exploring the stability of novel alloys such as quasicrystals, but their formation conditions and the nucleation-growth mechanisms occurring during shock experiments remain largely elusive. Here, the authors provide a summary of quasicrystal shock-syntheses and discuss the advantages and difficulties caused by the experimental complexity. [ABSTRACT FROM AUTHOR]

Published

2024

9. Isotopic variation of non-carbonaceous meteorites caused by dust leakage across the Jovian gap in the solar nebula.

Author

Homma, Kazuaki A, Okuzumi, Satoshi, Arakawa, Sota, and Fukai, Ryota

Subjects

*NATURAL satellites, *DUST, *METEORITES, *ORIGIN of planets, *METEOROIDS

Abstract

High-precision isotopic measurements of meteorites revealed that they are classified into non-carbonaceous (NC) and carbonaceous (CC) meteorites. One plausible scenario for achieving this grouping is the early formation of Jupiter, because massive planets can create gaps that suppress the mixing of dust across the gap in protoplanetary disks. However, the efficiency of this suppression by the gaps depends on dust size and the strength of turbulent diffusion, allowing some fraction of the dust particles to leak across the Jovian gap. In this study, we investigate how isotopic ratios of NC and CC meteorites are varied by the dust leaking across the Jovian gap in the solar nebula. To do this, we constructed a model to simulate the evolution of the dust size distribution and the |$^{54}$| Cr-isotopic anomaly |$\varepsilon ^{54}$| Cr in isotopically heterogeneous disks with Jupiter. Assuming that the parent bodies of NC and CC meteorites are formed in two dust-concentrated locations inside and outside Jupiter's orbit, referred to as the NC reservoir and the CC reservoir, we derive the temporal variation of |$\varepsilon ^{54}$| Cr at the NC and CC reservoirs. Our results indicate that substantial contamination from CC materials occurs at the NC reservoir in the fiducial run. Nevertheless, the values of |$\varepsilon ^{54}$| Cr at the NC reservoir and the CC reservoir in the run are still consistent with those of NC and CC meteorites formed around |$2\:$| Myr after the formation of calcium–aluminum-rich inclusions (Sugiura & Fujiya 2014 , Meteorit. Planet. Sci. 49, 772). Moreover, this dust leakage causes a positive correlation between the |$\varepsilon ^{54}$| Cr value of NC meteorites and the accretion ages of their parent bodies. [ABSTRACT FROM AUTHOR]

Published

2024

10. Raman spectroscopy analysis of artificial space weathering effects of NWA 10580 CO3 meteorite.

Author

Kereszturi, Ákos, Biri, Sándor, Gyollai, Ildikó, Juhász, Zoltán, Király, Csilla, Rácz, Richárd, Rezes, Dániel, Sulik, Béla, Szabó, Máté, Szalai, Zoltán, Szávai, Péter, and Szklenár, Tamás

Subjects

*CHLORITE minerals, *SPACE environment, *METEORITES, *CRYSTAL lattices, *RAMAN spectroscopy

Abstract

A medium‐grade, poorly weathered CO3‐type meteorite was subjected to artificial space weathering by 1 keV protons in three subsequent steps, with gradually increasing doses from 1011 to 1017 protons per cm2. The resulting mineral modifications were identified by Raman spectroscopy, with specific emphasis on main minerals such as olivine (bands: 817, 845 cm−1), pyroxene (1007 cm−1), and partly amorphous feldspar (509 cm−1), considering variation in band shift and bandwidth (full width at half maximum, FWHM). After the first and second irradiations, variable band position changes were observed, probably from metastable alterations by Mg loss of the minerals, while the third stronger irradiation showed band shift dominated by amorphization. The olivine and pyroxene show weak increase in FWHM after the first irradiation, while more changes happened after the second and third irradiations. The flux after the third irradiation was higher than in other works, caused stronger damage in crystal lattice, partly resembling to dimerization as described by shock metamorphism. The glassy feldspar was characterized by high FWHM values already at the beginning, indicating weak crystallinity already that become even less crystallized, thus their bands disappeared after the third irradiation. Bands of hydrous minerals (goethite clay, chlorite) were not visible after the third irradiation, confirming some earlier results in the literature. Based on our results, moderately fresh surfaces could show stochastic but small spectral differences compared to the fresh most meteorites by metastable mineral alterations. The interpretation of Raman spectra of heavily space‐weathered surfaces could further benefit from the joint evaluation of alteration induced by both shock impact alteration and space weathering. [ABSTRACT FROM AUTHOR]

Published

2024

11. Chondrule sizes within the CM carbonaceous chondrites and measurement methodologies.

Author

Floyd, C. J., Benito, S., Martin, P.‐E., Jenkins, L. E., Dunham, E., Daly, L., and Lee, M. R.

Subjects

*CHONDRULES, *SOLAR oscillations, *CHONDRITES, *AFFINITY groups, *METEORITES

Abstract

The sizes of chondrules are a valuable tool for understanding relationships between meteorite groups and the affinity of ungrouped chondrites, documenting temporal/spatial variability in the solar nebula, and exploring the effects of parent body processing. Many of the recently reported sizes of chondrules within the CM carbonaceous chondrites differ significantly from the established literature average and are more closely comparable to those of chondrules within CO chondrites. Here, we report an updated analysis of chondrule dimensions within the CM group based on data from 1937 chondrules, obtained across a suite of CM lithologies ranging from petrologic subtypes CM2.2 to CM2.7. Our revised average CM chondrule size is 194 μm. Among the samples examined, a relationship was observed between petrologic subtype and chondrule size such that chondrule long‐axis lengths are greater in the more highly aqueously altered lithologies. These findings suggest a greater similarity between the CM and CO chondrites than previously thought and support arguments for a genetic link between the two groups (i.e., the CM‐CO clan). Using the 2‐D and 3‐D data gathered, we also apply numerous stereological corrections to examine their usefulness in correcting 2‐D chondrule measurements within the CM chondrites. Alongside this analysis, we present the details of a standardized methodology for 2‐D chondrule size measurement to facilitate more reliable inter‐study comparisons. [ABSTRACT FROM AUTHOR]

Published

2024

12. Cosmic‐ray exposure age accumulated in near‐Earth space: A carbonaceous chondrite case study.

Author

Shober, Patrick M., Caffee, Marc W., and Bland, Phil A.

Subjects

*PROBABILITY density function, *ORBITS (Astronomy), *CHONDRITES, *METEORITES, *METEOROIDS, *ASTEROIDS, *RESONANCE

Abstract

This study investigates the expected cosmic‐ray exposure (CRE) of meteorites if they were to be ejected by a near‐Earth object, that is, from an object already transferred to an Earth‐crossing orbit by an orbital resonance. Specifically, we examine the CRE ages of CI and CM carbonaceous chondrites (CCs), which have some of the shortest measured CRE ages of any meteorite type. A steady‐state near‐Earth carbonaceous meteoroid probability density function is estimated based on the low‐albedo near‐Earth asteroid population, including parameters such as the near‐Earth dynamic lifetime, the impact probability with the Earth, and the orbital parameters. This model was then compared to the orbits and CRE ages of the five CC falls with precisely measured orbits: Tagish Lake, Maribo, Sutter's Mill, Flensburg, and Winchcombe. The study examined two meteoroid ejection scenarios for CI/CM meteoroids: Main Belt collisions and ejections in near‐Earth space. The results indicated that applying a maximum physical lifetime in near‐Earth space of 2–10 Myr to meteoroids and eliminating events evolving onto orbits entirely detached from the Main Belt (Q < 1.78 au) significantly improved the agreement with the observed orbits of carbonaceous falls. Additionally, the CRE ages of three of the five carbonaceous falls have measured CRE ages one to three orders of magnitude shorter than expected for an object originating from the Main Belt with the corresponding semi‐major axis value. This discrepancy between the expected CRE ages from the model and the measured ages of three of the carbonaceous falls indicates that some CI/CM meteoroids are being ejected in near‐Earth space. This study proposes a nuanced hypothesis involving meteoroid impacts and tidal disruptions as significant contributors to the ejection and subsequent CRE age accumulation of CI/CM chondrites in near‐Earth space. [ABSTRACT FROM AUTHOR]

Published

2024

13. The occurrence of metallic copper and redistribution of copper in the shocked Suizhou L6 chondrite.

Author

Xie, Xiande, Gu, Xiangping, and Yang, Yiping

Subjects

*ELECTRON probe microanalysis, *IRON meteorites, *METEORITES, *METALS, *VEINS, *SIDEROPHILE elements, *COPPER

Abstract

Copper possesses very strong chacophile properties, but under the conditions found in meteorites, its behavior is like that of siderophile elements. The Suizhou meteorite is a highly shocked L6 chondrite. Troilite and taenite are considered the main primary carrier of copper in this meteorite, and the post-shock thermal episode is considered the main reason that elemental Cu migrates from its original host phase and forms metallic grains. The Suizhou meteorite contains a few very thin shock melt veins. The occurrence and behavior of metallic copper in this meteorite were studied by optical microscopic examination, electron microprobe analyses, and high-resolution X-ray elemental intensity mapping. Our results show that metallic copper is abundant in the Suizhou chondritic rock. Metallic copper grains adjacent to small troilite grains inside FeNi metal are the most common occurrence, and those at the FeNi metal–troilite interface are the second most common case. The metallic copper grains occurring at the interface of FeNi metal/troililte and silicate are rather rare. Metallic copper grains are not observed within the Suizhou shock veins, Instead, Cu in elemental form is transferred through shock metamorphism into FeNi metal + troilite intergrowths. Four different occurrence types of Cu in the FeNi metal + troilite intergrowths have been identified: the concentrations of Cu in the FeNi + FeS intergrowths for four occurrence types are rather close, we estimate it might be lower than 1 wt%. [ABSTRACT FROM AUTHOR]

Published

2024

14. Detection of fireballs in the Lightning Imager data.

Author

Kokou, Pierre

Subjects

*LIGHT curves, *SPACE debris, *SPACE vehicles, *METEORS, *LIGHTNING

Abstract

The Meteosat Third Generation - Imager 1 satellite, launched on 13 December 2022, features the first Lightning Imager instrument, a high-speed optical camera providing near real-time lightning detection over Europe and Africa. This study demonstrates that signatures of fireballs (i.e. bright meteors) can be detected in Lightning Imager data. We describe a method to analyse this data to determine the timing, light signal, and trajectory of fireballs, highlighting the instrument's usefulness for bright meteor observation and proposing avenues for further research. By using known fireball locations and timings from external sources, the Lightning Imager data can be filtered to isolate 'lightning events' induced by the meteor. From this data set, the fireball light curve is computed by aggregating signal increases measured by instrument pixels. A trajectory is then deduced using a weighted average of pixel locations based on observed intensity. Three examples of fireballs detected by the Lightning Imager are presented, including a man-made meteor from space debris re-entry, with estimated timing, light curves, and trajectories. [ABSTRACT FROM AUTHOR]

Published

2024

15. Update on the 53Mn-53Cr ages of dolomite in the Ivuna CI chondrite and asteroid Ryugu sample.

Author

Sugawara, Shingo, Fujiya, Wataru, Kawasaki, Noriyuki, Sakamoto, Naoya, Yamaguchi, Akira, and Yurimoto, Hisayoshi

Subjects

*SECONDARY ion mass spectrometry, *CARBONATE minerals, *DOLOMITE, *CALCITE, *METEORITES, *SOLAR system, *ASTEROIDS, *CHONDRITES

Abstract

Aqueous alteration in planetesimals is one of the earliest geological processes in the solar system. The timing of aqueous alteration sheds light on the timescale of material evolution through water–rock interaction in small bodies. The 53Mn-53Cr decay system, where a short-lived radionuclide 53Mn decays to 53Cr with a half-life of 3.7 Myr, is a powerful tool for dating carbonates in primitive meteorites that formed during aqueous alteration. In CI chondrites and samples returned from asteroid Ryugu, a major carbonate mineral is dolomite (CaMg(CO 3) 2) and could be dated precisely because of their relatively high Mn abundances. However, the lack of a proper dolomite standard for secondary ion mass spectrometry (SIMS) hinders us from obtaining accurate Mn/Cr ratios of carbonates, resulting in erroneous formation ages. In this work, we synthesized Mn-, Cr-, and Fe-bearing crystalline dolomite as standard materials and evaluated the relative sensitivity factor (RSF) of Mn/Cr for SIMS analysis, namely, the ratio of Mn/Cr obtained using SIMS to true Mn/Cr. We found that the RSF values of the dolomite standards range from 0.8 to 0.9, slightly higher than that of calcite (CaCO 3) (∼0.7), and increase with their Fe contents. We used the newly evaluated RSF values to date dolomite in the Ivuna CI chondrite and obtained an initial 53Mn/55Mn ratio of (3.95 ± 0.49) × 10−6 (95 % confidence interval) and the corresponding absolute age of 4564.0 + 0.6/−0.7 Ma. Our new initial 53Mn/55Mn ratio is 26 ± 19 % higher than that obtained by a previous study for the same dolomite grain using a calcite standard. This difference is consistent with the difference between the RSF values of dolomite and calcite. Based on these results, we updated the initial 53Mn/55Mn ratio previously reported for dolomite in the Ryugu sample A0058 to be (3.21 ± 0.66) × 10−6, which corresponds to an absolute age of 4562.8 + 1.0/−1.2 Ma. This age seems to be the best estimate for the formation age of dolomite in Ryugu currently available. [ABSTRACT FROM AUTHOR]

Published

2024

16. Isotopic evidence for a common parent body of IIG and IIAB iron meteorites.

Author

Anand, Aryavart, Spitzer, Fridolin, Hopp, Timo, Windmill, Richard, Kruttasch, Pascal, Burkhardt, Christoph, Dauphas, Nicolas, Greenwood, Richard, Hofmann, Beda, Mezger, Klaus, and Kleine, Thorsten

Subjects

*IRON meteorites, *LIQUID iron, *METEORITES, *ISOTOPES, *MELTING

Abstract

Magmatic iron meteorites are thought to sample the metallic cores of differentiated planetesimals and are subdivided into several chemical groups, each representing a distinct parent body. The only exceptions are the groups IIAB and IIG, which have been proposed to sample two immiscible melts from the same core. To test this model, we report the first Fe, Ni, O, and Cr isotope data for IIG iron meteorites and the first high-precision O isotope data for IIAB iron meteorites. The new data demonstrate that IIG iron meteorites belong to the non-carbonaceous (NC) meteorites. This is evident from the isotope anomaly of each of the four elements investigated, where the IIG irons always overlap with the compositions of NC meteorites but are distinct from those of carbonaceous (CC) meteorites. Moreover, among the NC meteorites and in particular, the NC irons, the isotopic composition of the IIG irons overlaps only with that of the IIAB irons. The combined Fe-Ni-O-Cr isotope data for IIAB and IIG iron meteorites, therefore, reveal formation from a single isotopic reservoir, indicating a strong genetic link between the two groups. The indistinguishable isotopic composition of the IIAB and IIG irons, combined with chemical evidence for the formation of IIG irons as late-stage liquids of the IIAB core, strongly suggests that both groups originate from the same core. The results underscore the strength of utilizing multiple elements and their isotopic compositions to establish genetic links among meteorites, rather than using a single element. They also highlight the significance of integrating multiple geochemical tracers and petrologic observations to accurately determine genetic relationships and the formation of meteorites within the same parent body. [ABSTRACT FROM AUTHOR]

Published

2024

17. Atmospheric entry and strewn fields estimation for rubble-pile meteoroids.

Author

Feng, Chengfan, Zeng, Xiangyuan, Li, Ziwen, and Gan, Qingbo

Subjects

*DISCRETE element method, *METEOROIDS, *INDUCTIVE effect, *EQUATIONS of state, *METEORITES

Abstract

One of the potentially catastrophic risks to human survival is the impact of a meteorite on Earth. When a meteoroid enters the atmosphere at an ultra-high speed, a series of complex evolution processes occur, mainly including ablation, fragmentation, airburst, and ground impact. This paper proposes a new systematic dynamical method for simulating the entire process of a meteoroid entering the atmosphere. In the new method, the DEM (Discrete Element Method) model is utilized to describe the initial structure and shape of a rubble-pile meteoroid. A combination of an aerodynamic trajectory model, a thermal ablation model, and an airburst model is introduced to simulate the entry process. Particularly, the Jone-Wilkins-Lee state equation is employed to characterize the large-scale airburst phenomenon caused by the internal expansion of the meteoroid. Referring to the observational data of the Chelyabinsk meteorite event, this paper parametrically simulates the trajectories, ablation, fragmentation, and airburst, and predicts the strewn field of different-shaped meteoroids. Compared with existing debris cloud models, this method considers the shape effect of rubble-pile meteoroids and can obtain the strewn field as a side effect. Numerical validation is carried out, indicating the result of the new method is more in line with the actual scenarios. [ABSTRACT FROM AUTHOR]

Published

2024

18. Haasttse‐baad Tessera Ring Complex: A Valhalla‐Type Impact Structure on Venus?

Author

López, I., Bjonnes, E., and Hansen, V. L.

Subjects

GEOLOGICAL maps, GEOLOGICAL mapping, MARS (Planet), MERCURY (Planet), RHEOLOGY, IMPACT craters, METEORITES, LUNAR craters, VENUS (Planet)

Abstract

Venus preserves ∼1,000 impact craters, yet to date no impact basins larger than 300 km in diameter—common in the oldest terrains on Mercury, Mars and the Moon—are recognized on Venus. The tessera terrain is Venus' oldest recognized terrain. We describe a ∼1,500 km‐diameter concentric ring‐graben complex preserved on Haasttse‐baad Tessera, Venus that we identify as the Haasttse‐baad Tessera Ring Complex (HTRC). Based on geologic relations and numerical modeling, we propose that the HTRC may represent a Valhalla‐type multiring impact basin formed late during the evolution of its host ribbon‐tessera terrain (rtt). Formation of Valhalla‐type impact basins could involve a unique three‐layer target rheology with a thin elastic layer above a low viscosity layer above a deep strong layer. This multi‐layer rheological sandwich is consistent with crustal rheology previously proposed for the formation of Venus' rtt. If the HTRC is a Valhalla‐type impact basin, it would be Venus' oldest, and currently largest, impact structure, providing a rare window into Venus' ancient past and with implications for early crustal processes on Venus. Plain Language Summary: Venus preserves ∼1,000 impact craters, but no craters larger than 300 km—common on Mercury, Mars, and Moon—are recognized. We describe a large circular structure (∼1,500 km‐diameter) that formed on tessera terrain, Venus' oldest recognized surface type. The structure consists of concentric circular troughs that cut the tessera surface; geologic mapping shows that the structure formed late during tessera formation. We discuss the different mechanisms for forming large circular features marked by concentric rings of structures, and propose that it could be an example of a large impact basin named Valhalla‐type impact basin after a structure present in Jupiter's moon Callisto. Previous research suggests that the formation of these impact basins likely involves a distinctive layering in the impact site consisting of a sandwich of layers with different strengths (strong‐weak‐strong), a configuration previously proposed as necessary to form the host tessera terrain. Numerical models show that forming the circular structure as a Valhalla‐type impact basin is possible if a large meteorite crashes into this three‐layer crust. This unique structure, which might represent a very old and large impact structure, could provide a rare window into Venus' ancient past. Key Points: We describe a unique ∼1,500 km‐diameter concentric ring complex and present detailed geologic maps of the structure and its host tesseraWe propose that this structure may represent a Valhalla‐type impact structure, as supported by geologic mapping and numerical modelingIf the hypothesis is valid, the complex is the largest impact structure recognized on Venus, with implications for early planet processes [ABSTRACT FROM AUTHOR]

Published

2024

19. Oriented Acicular Rutile Inclusions in Eclogites: Exsolutions From Majoritic Garnet or Shock Needles?

Author

Yang, Jian‐Jun, Xu, Hai‐Jun, and Hirajima, Takao

Subjects

TECTONIC exhumation, SEISMIC waves, PLAGIOCLASE, SEISMIC response, METEORITES, GARNET, RUTILE

Abstract

Oriented rutile needles (ORNs) forming a triangular network on the cross sections of garnet crystals have been widely used together with omphacite inclusions as evidence for exsolution from a majoritic garnet and exhumation of the host rocks from great depths (>200 km) in the Earth. A coronitic eclogite at Yangkou in the Chinese Su‐Lu high‐pressure metamorphic belt contains ORNs that are only found in the reddish cores of garnet porphyroblasts. The texture formed by the ORNs is not restricted to garnet but extends into the coexisting other minerals, which together form pseudomorphs after augite. Therefore, the ORNs are not specifically related to the host garnet and cannot be exsolutions therefrom. The outer zones of the garnet porphyroblasts in contact with plagioclase pseudomorphs are pale and rutile‐free but contain minute inclusions of omphacite, quartz, kyanite, phengite, and K‐feldspar, typical of coronitic garnet between augite and plagioclase. Electron backscatter diffraction reveals no optimum matching of the low index crystallographic directions of rutile and garnet as required by an exsolution mechanism. On the other hand, the ORNs resemble the amorphous lamellae in quartz and zircon in meteorite and seismic shocked rocks, and are inferred to have crystallized earlier in seismic shocked augite and were then overgrown by the host minerals. By contrast, the rutile particles in garnet cataclasites in a nearby eclogite breccia display deformed and explosive patterns and random crystallographic orientations. All these observations are best explained by the seismic shock compression and rarefaction scenario proposed earlier. Plain Language Summary: Oriented rutile needles typically forming a triangular network on the cross sections of high‐pressure garnet crystals have been widely used as evidence for exsolution from a higher‐pressure (Si‐rich) garnet and exhumation of the host rocks from depths greater than diamond could indicate. However, such an interpretation is questionable with regard to the crystallographic orientation relationships between the rutile and the garnet host, whether such relationships are sufficient evidence for an exsolution origin, and whether or not the garnet system was open to fluid/melt such that great depths may not be necessary for the formation of the rutile. This issue is of utmost importance as it determines how deep human beings can look directly into the Earth via rock samples other than those brought up by mantle‐derived magmas. Here we report the occurrence of rutile needles not only in garnet but also in coexisting other minerals, forming a coherent texture. This means that the rutile needles are not specifically related to garnet and therefore cannot be exsolutions therefrom. On the other hand, the rutile texture is comparable to the amorphous lamellae in meteorite and seismic shocked rocks, suggesting that they crystallized in response to seismic shock waves. A radiating pattern of rutile particles with random crystallographic orientations in a crushed grain of garnet implies explosion and the existence of a pressure release wave. Key Points: Oriented rutile needles occur only in the pseudomorphs after augite forming the cores of garnet porphyroblasts in an eclogitized gabbroThe rutile needles extend through garnet into the coexisting other minerals; thus, they are not exsolutions from any of the host mineralsThe texture of the rutile resembles shock lamellae in shocked quartz and zircon, suggesting that they formed in seismic shocked augite [ABSTRACT FROM AUTHOR]

Published

2024

20. Synthesis of Si-Fe Chondrule-like Dust Analogues in RF Discharge Plasmas.

Author

Baikaliyev, Akdaulet, Abdirakhmanov, Assan, Orazbayev, Sagi, Ussenov, Yerbolat, Brodsky, Alexander, Aitzhanov, Madi, Akhanova, Nazym, Dosbolayev, Merlan, Gabdullin, Maratbek, Ramazanov, Tlekkabul, and Batryshev, Didar

Subjects

METEORITES, HIGH-frequency discharges, SPACE environment, GLOW discharges, ELECTRIC discharges

Abstract

Chondrules are tiny particles that occur in stony meteorites and are considered as the building blocks of early asteroids and planets. It is believed that they were formed by the fast heating of the dust in the solar nebula. To date, there is no lab-scale experimental study of the formation of chondrules from the initial gas phase precursors following fast heating and crystallisation. The motivation of this work is a pre-trial study of the formation of chnodrule-like particles. The formation of meteorites in the space environment is associated with the aggregation of small particles or molecular clouds under the influence of shock waves or high-energy gas discharges in the solar nebula. In this work, the properties of product formation at the nanoscale-level were investigated using different feedstock materials which are the dominant elements in the meteorite. The structural and morphological properties of the synthesised Si-Fe nanomaterials were analysed by scanning/transmission electron microscopy (SEM/TEM), and chemical composition was analysed by X-ray energy-dispersive spectroscopy (EDS). The identification of crystalline phases was carried out by X-ray diffraction (XRD), whereas the presence of an Fe-Si system in the synthesised particles was demonstrated by Mössbauer spectroscopy. The obtained materials were exposed to the relatively high-energy pulsed plasma beam on the substrate with the aim to emulate the possible fast heating and melting of the formed nanoparticles. The formation steps of growing synthetic (engineered) chondro-like particles and nanostructures in laboratory conditions is discussed. [ABSTRACT FROM AUTHOR]

Published

2024

21. Finely layered CM2 carbonaceous chondrites may be analogs for layered boulders on asteroid (101955) Bennu.

Author

Jawin, Erica R., McCOY, Timothy J., Melendez, Lisette E., Corrigan, Catherine M., Righter, Kevin, and Connolly, Harold C. Jr

Subjects

*METEORITES, *CHONDRITES, *BOULDERS, *COLLECTIONS

Abstract

Orbital observations of Bennu revealed a surface covered in boulders that are most similar among meteorites in our collections to aqueously altered carbonaceous chondrites, and initial analyses of the returned Bennu sample have begun to reveal insights into Bennu's origins. We identified a suite of paired CM2 chondrite meteorites that have a finely layered texture and bear a striking similarity, although at a different scale, to rugged, layered boulders on Bennu. We investigated the nature and potential origin of this layered texture by performing a petrofabric analysis on samples MET 00431, 00434, and 00435. We developed a micro‐geospatial mapping framework that is more commonly used for landscape‐scale investigations. Our results reveal a pervasive fracture network that exhibits a similar orientation to flattened particles dominated by tochilinite–cronstedtite intergrowths (TCI). We propose that their petrofabrics originated from a low‐energy impact on the parent body that occurred after the main period of aqueous alteration halted. The impactdeformed TCI (which formed during earlier aqueous alteration) and generated the fractures. We propose that the sample from Bennu may contain particles with similar layered textures to these meteorites which, if present, would likewise indicate the dominant role of impacts and aqueous alteration on Bennu's parent body. [ABSTRACT FROM AUTHOR]

Published

2024

22. Cosmogenic radionuclides in meteorites from the Otway Massif blue ice area, Antarctica: An unusual, well‐preserved H5 chondrite strewn field.

Author

Welten, Kees C., Caffee, Marc W., Kress, Monika E., Giscard, Marlene D., Jull, A. J. Timothy, Harvey, Ralph P., and Schutt, John

Subjects

*CHONDRITES, *ICE fields, *METEORITES, *RADIOISOTOPES, *ATMOSPHERIC models, *METEOROIDS

Abstract

The US Antarctic Search for Meteorites (ANSMET) discovered a dense cluster of 88 ordinary chondrites with a total mass of more than 100 kg on a blue ice area (BIA) of 1.6 × 0.3 km2 near the Otway Massif, Grosvenor Mountains, Antarctica. The larger masses (weighing up to 29 kg) were found at one end of an oval‐shaped pattern and the smaller masses (50–200 g) at the other end. We measured concentrations of the cosmogenic radionuclides 10Be (half‐life—1.36 × 106 year) and 36Cl (3.01 × 105 year) in the metal fraction of 17 H chondrites, including 14 fragments of this cluster, to verify the hypothesis that this meteorite cluster on the Otway Massif BIA represents a meteorite strewn field produced by the atmospheric breakup of a single meteoroid. The 10Be and 36Cl concentrations confirm that 10 out of 14 H chondrites from different locations within this small area are paired fragments of the same meteorite fall, while the four other H chondrites represent two additional—smaller—falls. The radionuclides suggest a pre‐atmospheric mass of 200–400 kg for the large pairing group, suggesting that 25%–50% of the meteoroid survived atmospheric entry. Based on the distribution of the paired H chondrites and evidence of their common cosmic‐ray exposure history in space, we conclude that most of the 88 meteorites within this small area represent a meteorite strewn field. The small size of the strewn field suggests that the meteoroid entered at a steep angle (>60°), while the low amount of fusion crust on most meteorite surfaces most likely indicates atmospheric break up at low altitude, while additional fragmentation of a large surviving fragment may have occurred during impact on the ice. This well‐documented strewn field provides a good opportunity to apply model simulations of the atmospheric fragmentation of this object as a function of entry angle, velocity, and meteoroid strength. Cosmogenic 14C analyses in two members of the Otway Massif pairing group yield a terrestrial age of 15.5 ± 1.5 kyr, which represents the time elapsed since this meteorite fell on Earth. The excellent preservation of an Antarctic meteorite strewn field suggests that the Otway Massif BIA represents a relatively stagnant blue ice field. [ABSTRACT FROM AUTHOR]

Published

2024

23. Shock‐induced pervasive remelting of Fe sulfides in the basaltic shergottite Northwest Africa 14672: A benchmark for shock stages S6/S7 on Mars.

Author

Lorand, Jean‐Pierre, Pont, Sylvain, Hewins, Roger H., and Zanda, Brigitte

Subjects

*MARTIAN meteorites, *PYRRHOTITE, *ZONE melting, *METEORITES, *RESORPTION (Physiology), *METAL sulfides

Abstract

Northwest Africa (NWA) 14672, the most highly shocked Martian meteorite so far, has experienced >50% melting, compatible with peak pressure >~65 Gpa, at a transition stage 6/7. Despite these extreme shock conditions, the meteorite still preserves a population of "large" Fe sulfide blebs from the pre‐shock igneous assemblage. These primary blebs preserve characteristics of basaltic shergottites in term of modal abundance, preferential occurrence in interstitial pores along with late‐crystallized phases (ilmenite, merrillite), and Ni‐free pyrrhotite compositions. Primary sulfides underwent widespread shock‐induced remelting, as indicated by perfect spherical morphologies when embedded in fine‐grained silicate melt zones and a wealth of mineral/glass/vesicle inclusions. Extensive melting of Fe‐sulfides is consistent with the decompression path experienced by NWA 14672 after the peak shock pressure at ~70 GPa. Primary sulfides acted as preferential sites for nucleation of vesicles of all sizes which helped sulfur degassing during decompression, leading to partial resorption of Fe‐sulfide blebs and reequilibration of pyrrhotite metal/sulfur ratios (0.96–0.98) toward the low oxygen fugacity conditions indicated by Fe‐Ti oxides hosted in fine‐grained materials. The extreme shock intensity also provided suitable conditions for widespread in situ redistribution of igneous sulfur as micrometric globules concentrated in glassy portions of fine‐grained lithologies. These globules exsolved early on quenching, allowing dendritic skeletal Fe‐Ti oxide overgrowths to nucleate on sulfides. [ABSTRACT FROM AUTHOR]

Published

2024

24. A mineralogical and isotopic study of the historic monomict eucrite Padvarninkai.

Author

Barrett, T. J., King, A. J., Degli‐Alessandrini, G., Hammond, S. J., Humphreys‐Williams, E., Schmidt, B., Greenwood, R. C., Abernethy, F. A. J., Anand, M., and Rudnickaitė, E.

Subjects

*OXYGEN isotopes, *PLAGIOCLASE, *PETROLOGY, *PYROXENE, *METEORITES

Abstract

The Padvarninkai meteorite is a relatively understudied eucrite, initially misclassified as a shergottite given its strong shock characteristics. In this study, a comprehensive examination of the petrology; mineral composition; major, minor, and trace element abundances; and isotopic composition (C, O) is presented. Padvarninkai is a monomict eucrite consisting of a fine to coarse‐grained lithology and impact melt veins. Pyroxene grains are typically severely fractured and mosaicked whilst plagioclase is either partially or totally converted to maskelynite. Based on shock features observed in pyroxene, plagioclase, and apatite, Padvarninkai can be given a shock classification of M‐S4/5. Despite the high shock experienced by this sample, some of the original igneous textures remain. Compositionally, Padvarninkai is a main group eucrite with a flat REE pattern (~10–12 × CI) and elevated Ni abundances. Whilst both new and literature oxygen isotopes are similar to other eucrites, however, Padvarninkai displays an anomalously high δ13C value. To reconcile the high Ni and δ13C value, impact contamination modeling was conducted. These models could not reconcile both the high Ni and δ13C value with the eucritic δ18O values, arguing against impact as a source for these anomalies. [ABSTRACT FROM AUTHOR]

Published

2024

25. The formation of volatile‐bearing djerfisherite in reduced meteorites.

Author

Wilbur, Zoë E., McCoy, Timothy J., Corrigan, Catherine M., Barnes, Jessica J., Brown, Sierra V., and Udry, Arya

Subjects

*MERCURY (Planet), *METEORITES, *CHONDRITES, *ENSTATITE, *METASOMATISM

Abstract

Enstatite meteorites, both aubrites and enstatite chondrites, formed under exceptionally reducing conditions, similar to the planet Mercury. Despite being reduced, the MESSENGER mission showed that the surface of Mercury is more enriched in volatiles (e.g., S, Na, K, Cl) than previously thought. To better understand the mineral hosts of these volatiles and how they formed, this work examines the chemistry and petrographic settings of a rare, K‐bearing sulfide called djerfisherite within enstatite chondrites and aubrites. The petrographic settings of djerfisherite within aubrites suggest this critical host of Cl formed after both the crystallization of troilite and exsolution of daubréelite. Djerfisherite is commonly observed as a rim on other sulfides and in contact with metal. We present an alteration model for djerfisherite formation in aubrite meteorites, whereby troilite and Fe‐Ni metal are altered through anhydrous, alkali‐ and Cl‐rich fluid metasomatism on the aubrite parent body to produce secondary djerfisherite. Moreover, we observe a loss of volatiles in djerfisherite within impact melted regions of the Miller Range 07139 EH3 chondrite and the Bishopville aubrite and explore the potential for impact devolatilization changes to sulfide chemistry on other reduced bodies in the Solar System. Vapor or fluid phase interactions are likely important in the formation of volatile‐rich phases in reduced systems. While most Na and K on the mercurian surface is expected to be hosted in feldspar, djerfisherite is likely a minor, but critical, reservoir for K, Na, and Cl. Djerfisherite present on reduced bodies, such as Mercury, may represent sulfides formed via late‐stage, primary metasomatism. [ABSTRACT FROM AUTHOR]

Published

2024

26. Origin of fabrics and olivine chemical variations preserved in brachinite and brachinite‐like achondrite meteorites.

Author

Gruber, Benjamin H., Nicklas, Robert W., Day, James M. D., Chin, Emily J., Ren, Minghua, and Bernard, Rachel E.

Subjects

*CRYSTAL texture, *EARTH'S mantle, *METEORITES, *ACHONDRITES, *LASER ablation, *LASER ablation inductively coupled plasma mass spectrometry, *INDUCTIVELY coupled plasma mass spectrometry

Abstract

Brachinites and brachinite‐like achondrites are olivine‐rich meteorites that represent materials after partial metal–silicate differentiation on multiple early Solar System bodies. Both meteorite types show macroscopic textures of olivine crystals, which make up >70 modal percent of their mineralogy. We investigated the orientations of olivine using electron backscatter diffraction (EBSD) and elemental compositions from paired brachinite‐like achondrites and one brachinite. The olivine orientations are characterized by a strong concentration of [010] axes with maxima perpendicular to the foliation/layering and a concentration of [001] axes distributed in a girdle or, in a few samples, as point maxima. Trace element abundances of the olivine in these meteorites determined using laser ablation inductively coupled plasma–mass spectrometry have uniformly low concentrations of sodium (<300 μg g−1), aluminum (<70 μg g−1), and titanium (<40 μg g−1) that are distinct from olivine in chondrites or within terrestrial lavas. Instead, brachinite and brachinite‐like olivine compositions broadly overlap those of olivine from melt‐depleted mantle lithologies on Earth. Evidence from olivine trace element geochemistry, in conjunction with mineral fabrics, supports that these meteorites formed as melt residues on their host planetary body(ies). [ABSTRACT FROM AUTHOR]

Published

2024

27. First widespread occurrence of rare phosphate chladniite in a meteorite, winonaite Graves Nunataks (GRA) 12510: Implications for phosphide–phosphate redox buffered genesis in meteorites.

Author

Anzures, Brendan A., Mccubbin, Francis M., Erickson, Timmons M., Jakubek, Ryan S., Fries, Marc D., and Le, Loan

Subjects

*IRON meteorites, *METEORITES, *PLANETARY interiors, *EARTH'S core, *DISCONTINUOUS precipitation, *CHROMITE, *APATITE

Abstract

The first widespread occurrence of rare Na-, Ca-, and Mg,Mn,Fe-bearing phosphate chladniite was observed in meteorite Graves Nunataks (GRA) 12510, which is a primitive achondrite that sits within the winonaite class. Numerous 1–500 μm chladniite grains were found, often on the margins between silicate clasts and the kamacite portions of the large metal veins that permeated through the sample. The largest chladniite grains are associated with merrillite, kamacite, taenite, troilite, albite, forsterite, diopside, and enstatite, with a few tiny chladniite grains and an apatite grain enclosed within merrillite. GRA 12510s average chladniite composition is Na2.7Ca1.25(Mg10.02Mn0.69Fe0.20)Σ10.91(PO4)9. Electron backscattered diffraction (EBSD) patterns indicate varying degrees of nucleation and growth of chladniite grains. Additionally, the first pure Raman spectrum of chladniite is described here, revealing primary ν1 bands at 954, 974, and especially 984 cm–1. The co-occurrence and close association of merrillite, apatite, chladniite, and P-bearing metallic phases within GRA 12510 suggests that the fO2 of IW-2 to IW-4 is an intrinsic property of the precursor chondritic material, and the phosphatephosphide reaction may have buffered the final winonaite and IAB iron meteorite phase assemblages. Altogether, chladniite appears to form alongside other phosphates, with their chemistries reflecting the diverse environment of their formation. Meteoritic chladniite likely formed through subsolidus oxidation of schreibersite, scavenging Na from albite, Ca from diopside, Mg from enstatite/forsterite, Fe from kamacite/taenite, and Mn from alabandite/chromite when available. A P0-P5+ redox-buffered environment also has implications for thermometry and fast cooling rates, although more experiments are needed to extrapolate powder reaction rates to those of larger crystals. Furthermore, phosphidephosphate buffered experiments may aid in investigating equilibrium chemistry at fO2 values between IW-2 and IW-4, which have been challenging to explore experimentally due to the limited availability of solid metal-metal oxide buffers between IW (Fe-FeO) and IW-5 (Cr-Cr2O3) at temperatures and pressures relevant to planetary interiors. Future investigations of phosphide-phosphate redox-buffered genesis at fO2 values between IW-2 and IW-4 have important implications for primitive meteorite constituents (e.g., CAI values), partially differentiated planetesimals and planets, including Mercury and core formation on Earth. [ABSTRACT FROM AUTHOR]

Published

2024

28. The 18 May 2024 Iberian superbolide from a sunskirting orbit: USG space sensors and ground-based independent observations.

Author

Peña-Asensio, E, Grèbol-Tomàs, P, Trigo-Rodríguez, J M, Ramírez-Moreta, P, and Kresken, R

Subjects

*SMALL solar system bodies, *NEAR-Earth objects, *ORBITS (Astronomy), *ATMOSPHERIC models, *METEORS, *METEOROIDS, *ASTEROIDS

Abstract

On 18 May 2024, a superbolide traversed the western part of the Iberian Peninsula, culminating its flight over the Atlantic Ocean and generating significant media attention. This event was caused by a weak carbonaceous meteoroid of 1 m, entering the atmosphere at 40.4 km s |$^{-1}$| with an average slope of 8.5 |$^\circ$|⁠. The luminous phase started at 133 km and ended at an altitude of 54 km. The meteoroid's heliocentric orbit had an inclination of 16.4 |$^\circ$|⁠ , a high eccentricity of 0.952, a semimajor axis of 2.4 au, and a short perihelion distance of 0.12 au. The superbolide was recorded by multiple ground-based stations of the Spanish Fireball and Meteorite Network and the European Space Agency, as well as by the U.S. Government sensors from space. Due to the absence of observable deceleration, we successfully reconciled satellite radiometric data with a purely dynamic atmospheric flight model, constraining the meteoroid's mass and coherently fitting its velocity profile. Our analysis shows a good agreement with the radiant and velocity data reported by the Center for Near-Earth Object Studies, with a deviation of 0.56 |$^\circ$| and 0.1 km s |$^{-1}$|⁠ , respectively. The presence of detached fragments in the lower part of the luminous trajectory suggests that the meteoroid was a polymict carbonaceous chondrite, containing higher-strength macroscopic particles in its interior due to collisional gardening, or a thermally processed C-type asteroid. The orbital elements indicate that the most likely source is the Jupiter-Family Comet region, aligning with the Solar and Heliospheric Observatory comet family, as its sunskirting orbit is decoupled from Jupiter. This event provides important information to characterize the disruption mechanism of near-Sun objects. [ABSTRACT FROM AUTHOR]

Published

2024

29. Tarda and Tagish Lake: Samples from the same outer Solar System asteroid and implications for D- and P-type asteroids.

Author

Schrader, Devin L., Cloutis, Edward A., Applin, Daniel M., Davidson, Jemma, Torrano, Zachary A., Foustoukos, Dionysis, Alexander, Conel M. O'D., Domanik, Kenneth J., Matsuoka, Moe, Nakamura, Tomoki, Zega, Thomas J., Brennecka, Gregory A., and Render, Jan

Subjects

*MARTIAN exploration, *SOLAR system, *CHONDRITES, *METEORITES, *ASTEROIDS, *PETROLOGY

Abstract

We report a comprehensive study of the ungrouped type 2 carbonaceous chondrite, Tarda, which fell in Morocco in 2020. This meteorite exhibits substantial similarities to Tagish Lake, Wisconsin Range 91600, and Meteorite Hills 00432, which are generally considered to have originated from a D-type asteroid(s). We constrain the compositions and petrologies of the materials present in a potential sample of a D-type asteroid by reporting the petrography, bulk chemical compositions, bulk H, C, N, Cr, and Ti isotopic compositions, reflectance spectra, and in situ chemical compositions of metals, sulfides, carbonates, and FeO-poor and FeO-rich chondrule silicates of Tarda. We also present new data for Tagish Lake. We then compare Tarda with the other Tagish Lake-like meteorites. Tarda and Tagish Lake appear to be from the same parent body, as demonstrated by their similar petrologies (modal abundances, chondrule sizes), mineral compositions, bulk chemical and isotopic compositions, and reflectance spectra. While the two other Tagish Lake-like meteorites, Wisconsin Range 91600 and Meteorite Hills 00432, show some affinities to Tagish Lake and Tarda, they also share similar characteristics to the Mighei-like carbonaceous (CM) chondrites, warranting further study. Similarities in reflectance spectra suggest that P-type asteroids 65 Cybele and 76 Freia are potential parent bodies of Tarda and the Tagish Lake-like meteorites, or at least have similar surface materials. Since upcoming spacecraft missions will spectrally survey D-type, P-type, and C-type Trojan asteroids (NASA's Lucy) and spectrally study and return samples from Mars' moon Phobos (JAXA's Martian Moons eXploration mission), which is spectrally similar to D-type asteroids, these meteorites are of substantial scientific interest. Furthermore, since Tarda closely spectrally matches P-type asteroids (but compositionally matches the D-type asteroid like Tagish Lake meteorite), P-type and D-type asteroids may represent fragments of the same or similar parent bodies. [ABSTRACT FROM AUTHOR]

Published

2024

30. Schreibersite oxidation under varied oxygen buffers.

Author

Feng, Tian, Omran, Arthur, Gull, Maheen, Schaible, Micah J., Orlando, Thomas M., and Pasek, Matthew A.

Subjects

*CHONDRITES, *OXIDATION states, *CALCIUM phosphate, *METEORITES, *PHOSPHIDES

Abstract

Phosphorus is often present in meteorites as the mineral schreibersite, in which P is in a reduced oxidation state as a phosphide. Phosphides such as schreibersite have been proposed to be important to the development of life on the earth and may serve as indicators of metamorphic grade on meteorite parent bodies. Here we investigate how synthetic schreibersite (as the iron end-member, Fe 3 P) oxidizes into calcium phosphates through reaction with silicates under high temperature conditions, at specific oxygen fugacities, and in the absence of water. We find that schreibersite readily oxidizes to phosphates at temperatures of 750–850 °C over a few weeks depending on the oxygen fugacity of the environment. The rate of this process is best matched by diffusion-limited kinetics. Therefore, the metamorphic heating timescale required to equilibrate phosphorus in meteoritic samples with small schreibersite grains (∼1 μm), such as in the type 3 ordinary chondrites (3.0–3.3), was short (10–100 days). [ABSTRACT FROM AUTHOR]

Published

2024

31. Micromechanical testing and property upscaling of planetary rocks: A critical review

Author

Yiwei Liu, Guoping Zhang, Jiangmei Qiao, and Xuhai Tang

Subjects

Meteorites, Planetary rock mechanics, Non-destructive testing, Upscaling method, Extraterrestrial construction, Space exploration, Mining engineering. Metallurgy, TN1-997

Abstract

Knowledge of the mechanical behavior of planetary rocks is indispensable for space explorations. The scarcity of pristine samples and the irregular shapes of planetary meteorites make it difficult to obtain representative samples for conventional macroscale rock mechanics experiments (macro-RMEs). This critical review discusses recent advances in microscale RMEs (micro-RMEs) techniques and the upscaling methods for extracting mechanical parameters. Methods of mineralogical and microstructural analyses, along with non-destructive mechanical techniques, have provided new opportunities for studying planetary rocks with unprecedented precision and capabilities. First, we summarize several mainstream methods for obtaining the mineralogy and microstructure of planetary rocks. Then, nondestructive micromechanical testing methods, nanoindentation and atomic force microscopy (AFM), are detailed reviewed, illustrating the principles, advantages, influencing factors, and available testing results from literature. Subsequently, several feasible upscaling methods that bridge the micro-measurements of meteorite pieces to the strength of the intact body are introduced. Finally, the potential applications of planetary rock mechanics research to guiding the design and execution of space missions are environed, ranging from sample return missions and planetary defense to extraterrestrial construction. These discussions are expected to broaden the understanding of the microscale mechanical properties of planetary rocks and their significant role in deep space exploration.

Published

2024

32. Machine learning applications on lunar meteorite minerals: From classification to mechanical properties prediction

Author

Eloy Peña-Asensio, Josep M. Trigo-Rodríguez, Jordi Sort, Jordi Ibáñez-Insa, and Albert Rimola

Subjects

Meteorites, Moon, Mineralogy, Machine learning, Mechanical properties, Mining engineering. Metallurgy, TN1-997

Abstract

Amid the scarcity of lunar meteorites and the imperative to preserve their scientific value, non-destructive testing methods are essential. This translates into the application of microscale rock mechanics experiments and scanning electron microscopy for surface composition analysis. This study explores the application of Machine Learning algorithms in predicting the mineralogical and mechanical properties of DHOFAR 1084, JAH 838, and NWA 11444 lunar meteorites based solely on their atomic percentage compositions. Leveraging a prior-data fitted network model, we achieved near-perfect classification scores for meteorites, mineral groups, and individual minerals. The regressor models, notably the K-Neighbor model, provided an outstanding estimate of the mechanical properties—previously measured by nanoindentation tests—such as hardness, reduced Young’s modulus, and elastic recovery. Further considerations on the nature and physical properties of the minerals forming these meteorites, including porosity, crystal orientation, or shock degree, are essential for refining predictions. Our findings underscore the potential of Machine Learning in enhancing mineral identification and mechanical property estimation in lunar exploration, which pave the way for new advancements and quick assessments in extraterrestrial mineral mining, processing, and research.

Published

2024

33. Nucleosynthetic Isotope Anomalies in Cosmochemistry and Geochemistry

Author

Bermingham, Katherine and Meyer, Brad

Published

2024

34. The slow neutron-capture process in stars.

Author

Vescovi, Diego

Subjects

*NEUTRON capture, *SOLAR system, *ASTROPHYSICS, *METEORITES, *INFORMATION retrieval

Abstract

Most elements heavier than iron in the Universe are produced through neutron captures. The solar system abundance distribution indicates that they were created primarily in two nucleosynthetic processes, the slow and the rapid processes. Here, we cover the fundamental aspects of the s-process. The ever-growing amount of information gathered from astronomical observations and analyses of stardust grains recovered from meteorites provides tight constraints on the mechanisms of the s-process and where it occurs. Comparison of chemical abundance patterns with stellar model predictions clearly identifies evolved low-mass and massive stars as the s-process astrophysical sites. [ABSTRACT FROM AUTHOR]

Published

2024

35. Nucleosynthesis in Type Ia Supernovae, Classical Novae, and Type I X-Ray Bursts. A Primer on Stellar Explosions.

Author

José, Jordi

Subjects

*SUPERNOVAE, *NUCLEOSYNTHESIS, *X-ray bursts, *NUCLEAR astrophysics, *NUCLEAR reactions, *METEORITES

Abstract

Nuclear astrophysics aims at unraveling the cosmic origins of chemical elements and the physical processes powering stars. It constitutes a truly multidisciplinary field, that integrates tools, advancements, and accomplishments from theoretical astrophysics, observational astronomy, cosmochemistry, and theoretical and experimental atomic and nuclear physics. For instance, the advent of high-energy astrophysics, facilitated by space-borne observatories, has ushered in a new era, offering a unique, panchromatic view of the universe (i.e., allowing multifrequency observations of stellar events); supercomputers are also playing a pivotal role, furnishing astrophysicists with computational capabilities essential for studying the intricate evolution of stars within a multidimensional framework; cosmochemists, through examination of primitive meteorites, are uncovering tiny fragments of stardust, shedding light on the physical processes operating in stars and on the mechanisms that govern condensation of stellar ejecta into solids; simultaneously, nuclear physicists managed to measure nuclear reactions at (or close to) stellar energies, using both stable and radioactive ion beam facilities. This paper provides a multidisciplinary view on nucleosynthesis accompanying stellar explosions, with a specific focus on thermonuclear supernovae, classical novae, and type I X-ray bursts. [ABSTRACT FROM AUTHOR]

Published

2024

36. 72 HOURS UNTIL IMPACT: What would we do if an asteroid was on a collision course with Earth? All About Space reveals the plan to save humanity from extinction

Author

Plummer, Libby

Subjects

Asteroids, Meteorites, Jupiter (Planet), Company business planning, Astronomy

Abstract

A civilisation-destroying asteroid may sound like the stuff of science fiction, but the threat is very real. These rocky fragments range in size from mere metres to hundreds of kilometres [...]

Published

2024

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

Author

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

Subjects

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

Abstract

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

Published

2024

38. Magmatic evolution of KREEP‐free lunar meteorite Asuka‐881757 inferred from sector‐zoned clinopyroxene, pyroxene symplectites, and thermodynamic modeling.

Author

Srivastava, Y., Basu Sarbadhikari, A., Yamaguchi, A., Takenouchi, A., Day, J. M. D., and Ubide, T.

Subjects

*LUNAR surface, *METEORITES, *PLAGIOCLASE, *LAVA flows, *GABBRO, *LUNAR craters

Abstract

Lunar basaltic meteorite Asuka‐881757 (A‐881757), a member of the source crater paired YAMM meteorites (Yamato‐793169, A‐881757, Miller Range 05035 and Meteorite Hills 01210), provides information on potassium‐rare earth element‐phosphorous (KREEP)‐free magmatic sources within the Moon. Asuka‐881757 is an unbrecciated and Fe‐rich (Mg# 36) gabbro with coarse pyroxene (2–8 mm) and plagioclase (1–3 mm). The coarse pyroxene preserves mm‐scale, near‐complete hour‐glass sector zoning with strong Ca and Fe partitioning, similar to some Fe‐rich Apollo basalts. In contrast to the most Mg‐rich Apollo basalts, A‐881757 contains various types of symplectites (~8 vol%) formed by the breakdown of pyroxferroite due to slow cooling, resembling a few extreme Fe‐rich (Mg# ≤$$ \le $$40) Apollo basalts. Petrographic observations and thermodynamic modeling suggest crystallizing in the order: Fe‐poor pyroxenes (Mg# 58–55) → co‐crystallized plagioclase and Fe‐rich pyroxenes (Mg# 49–20) → late‐stage assemblage including Fe‐augite, Fayalite, and Fe‐Ti oxides. Combining phase stability at variable P–T with petrographic observations, the minimum depth of formation of the A‐881757 parent magma can be constrained to between 60 and 100 km. KREEP‐free basalts (such as A‐881757 and the YAMM meteorites) originated from a relatively shallow mantle source and later underwent polybaric crystallization that occurred prior to eruption at the lunar surface. In contrast, the Apollo mare basalts mostly crystallized within lava flows from relatively deeper‐seated mantle sources. The crystallization of A‐881757 and other YAMM meteorites is unlike most Apollo basalts from the Procellarum KREEP terrane, and likely represent hidden cryptomare basalts close to lunar surface. [ABSTRACT FROM AUTHOR]

Published

2024

39. On the correlation between the enantiomeric excess of L-isovaline and the level of aqueous alteration in carbonaceous meteorites.

Author

Avnir, David, McCoustra, Martin Robert Stewart, and Dworkin, Jason P.

Subjects

*CIRCULAR dichroism, *METEORITES, *PARALLEL processing

Abstract

A positive correlation was observed between the enantiomeric excess (ee) of L-isovaline (L-iVal) and the degree of aqueous alteration (AqA) of carbonaceous meteorites. The origin of this remarkable phenomenon has remained enigmatic from two points of view: First, the correlation is between seemingly unrelated observables-nothing about AqA is of chiral characteristics; and second, following the accepted assumption that circularly polarized light (CPL) was the origin of the observed meteoritic ee of L-amino acids (AAs), it remined unclear why some of the observed levels of the ee of L-iVal in that correlation are significantly higher than those observed in laboratory simulations or those obtained from circular dichroism (CD) g-factor calculations. The current proposition accounting for this picture attributes late AqA conditions of the meteoritic parent bodies as providing the grounds for amplification of early initially CPL-generated low levels of L-ee. For reasons summarized below, this interpretation, which treats the CPL event and the AqA process as occurring in wide-time separated eras, is re-visited. An alternative interpretation of the observed correlation and of the high ee-values, is provided. It focuses on hydrophilic dust-aggregates clouds in wet star-forming regions in early presolar times, where both the CPL event and the grounds leading to the later AqA processes of the parent bodies, occurred. This mechanism removes the time separation between the initial ee formation and the AqA of the parent body, and replaces it with parallel processes, providing a scenario to the observation of high ee's without total destruction, and to the apparent AqA/L-ee correlation. Although iVal is at the focus of this report, the steps of the development of the alternative mechanism and the conclusions that arise from it, are relevant and applicable to the general observations of L-ee's of meteoritic AA's. [ABSTRACT FROM AUTHOR]

Published

2024

40. Elemental differentiation and isotopic fractionation during space weathering of Chang'E-5 lunar soil.

Author

Shi, Qingshang, He, Yongsheng, Zhu, Jian-Ming, Wang, Yang, Wu, Hongjie, Wang, Peijie, Yang, Ruyi, Sun, Aiying, Zhang, Yinchu, Wu, Guangliang, Wan, Ruoqi, Lu, Zhuo, Teng, Fang-Zhen, Li, Chunlai, Yang, Wei, Zhang, Chi, Han, Ziyan, and Ke, Shan

Subjects

*LUNAR soil, *SPACE environment, *RUBIDIUM, *ISOTOPIC fractionation, *RARE earth metals, *ALUMINUM oxide, *PLAGIOCLASE, *METEORITES

Abstract

To investigate the chemical variation during space weathering of young mare basalts, here we report elemental, radiogenic Sr-Nd and stable Fe-Mg-Ca isotopic data of Chang'E-5 sieved soils and breccias. From the coarse fraction to the fine one, the sieved soils display increasing Al 2 O 3 (10.34 wt%–13.36 wt%) and Sr (248 ppm–307 ppm) but decreasing FeO (23.50 wt%–20.22 wt%), MgO (6.88 wt%–5.78 wt%), FeO/Al 2 O 3 (2.27–1.51) and MgO/Al 2 O 3 (0.67–0.43). The contents of rare earth elements (except Eu) and high field strength trace elements do not vary with particle size but correlate with P 2 O 5 contents. Given the limited contribution from contamination by meteorites and exotic materials ejected far away from the landing site, these elemental variations can be explained by differential comminution and distribution behaviors of plagioclase and mesostasis phases. These sieved soils yield a Sm-Nd isochron age (1.84 ± 0.83 Ga) comparable to that of basaltic clasts obtained by U-Pb dating (∼2.0 Ga). However, their Rb-Sr isotopic system is disturbed as indicated by their relatively homogeneous 87Sr/86Sr (0.701425–0.701592) despite variable Rb/Sr (0.017–0.028). These results suggest the Sm-Nd isotopic system is more robust to impact disturbance during space weathering compared to the Rb-Sr isotopic system. Given that the bulk soil still plots on the 2.03 Ga Rb-Sr reference isochron from the pristine plagioclases in CE-5 basalts, this disturbance did not affect the Rb-Sr isotopic system on the bulk scale. The CE-5 bulk soil has higher Mg# (33.6), 87Rb/86Sr (0.06) and present-day 87Sr/86Sr (0.701542) than the mean composition of reported basaltic clasts (Mg#: ∼28; 87Rb/86Sr: ∼0.038; 87Sr/86Sr: ∼0.700941), possibly implying that the bedrocks in CE-5 landing site consist of multiple magma pulses. The δ56Fe (0.122 ± 0.002 ‰ to 0.199 ± 0.008 ‰) and δ26Mg (−0.204 ± 0.016 ‰ to −0.109 ± 0.006 ‰) of sieved CE-5 soils increase with decreasing particle sizes but their δ 44/42Ca (0.38 ± 0.04 ‰ to 0.44 ± 0.02 ‰) are relatively homogeneous. Mass balance modelling indicates that differential comminution has limited influence on the Fe-Mg-Ca stable isotopic compositions. We further dismiss the role of solar-wind sputtering, as Ca and Mg are more susceptible to sputtering and thus would be expected to show larger isotope fractionations compared to Fe, which is inconsistent with the observations. Free evaporation may explain the elevated δ56Fe and δ26Mg in fine fractions at given very limited depletion in FeO and MgO. The observed positive correlation between δ56Fe and δ26Mg, however, is much steeper than the slope expected for free evaporation, indicating also other mechanisms (e.g., Fe-Mg inter-diffusion). Since the CE-5 soil has a unique composition compared with Apollo and Luna soils, the chemical differentiation identified in this study provides new insights for establishing a connection between the chemistry and reflectance spectral properties of lunar soil. Our combined Fe-Mg-Ca isotopic study also provides a paradigm to distinguish the role of solar-wind sputtering and impact evaporation, and shows that the inter-particle diffusion process may be an important mechanism for the isotope fractionation among lunar soil components. [ABSTRACT FROM AUTHOR]

Published

2024

41. The Earth atmosphere‐like bulk nitrogen isotope composition obtained by stepwise combustion analyses of Ryugu return samples.

Author

Hashizume, Ko, Ishida, Akizumi, Chiba, Ayano, Okazaki, Ryuji, Yogata, Kasumi, Yada, Toru, Kitajima, Fumio, Yurimoto, Hisayoshi, Nakamura, Tomoki, Noguchi, Takaaki, Yabuta, Hikaru, Naraoka, Hiroshi, Takano, Yoshinori, Sakamoto, Kanako, Tachibana, Shogo, Nishimura, Masahiro, Nakato, Aiko, Miyazaki, Akiko, Abe, Masanao, and Okada, Tatsuaki

Subjects

*NITROGEN isotopes, *CHONDRITES, *METEORITES, *COMBUSTION, *AMMONIA, *ASTEROIDS

Abstract

The nitrogen isotope compositions of two samples returned from the asteroid Ryugu were determined using a stepwise combustion method, along with Ivuna (CI) and Y‐980115, a CI‐like Antarctic meteorite, as references. The two Ryugu samples A0105‐07 and C0106‐07 showed bulk δ15N values of +1.7 ± 0.5‰ and +0.2 ± 0.6‰, respectively, significantly lower than Ivuna with +36.4 ± 0.4‰, but close to Y‐980115 with +4.0 ± 0.3‰. The Ryugu samples are further characterized by C/N and 36Ar/N ratios up to 3.4× and 4.9× the value of Ivuna, respectively. Among all Ryugu samples and CI chondrites, a positive correlation was observed between nitrogen concentrations and δ15N values, with samples with lower nitrogen concentrations exhibiting lower δ15N. This trend is explained by a two‐component mixing model. One component is present at a constant abundance among all CI‐related samples, with a δ15N value around 0‰ or lower. The other varies in abundance between different samples, and exhibits a δ15N value of +56 ± 4‰. The first 15N‐poor endmember is seemingly tightly incorporated into a carbonaceous host phase, whereas the 15N‐rich endmember can be mobilized and decoupled from carbon, potentially because it is in the form of ammonia. Asteroid materials with volatile compositions that are similar to those reported here for the Ryugu samples are attractive candidates for the volatile sources among Earth's building blocks. [ABSTRACT FROM AUTHOR]

Published

2024

42. The iron oxidation state of Ryugu samples.

Author

Roskosz, Mathieu, Beck, Pierre, Viennet, Jean‐Christophe, Nakamura, Tomoki, Lavina, Barbara, Hu, Michael Y., Zhao, Jiyong, Alp, Esen E., Takahashi, Yoshio, Morita, Tomoyo, Amano, Kana, Yurimoto, Hisayoshi, Noguchi, Takaaki, Okazaki, Ryuji, Yabuta, Hikaru, Naraoka, Hiroshi, Sakamoto, Kanako, Tachibana, Shogo, Yada, Toru, and Nishimura, Masahiro

Subjects

*MAGHEMITE, *CLAY minerals, *METEORITES, *MOSSBAUER spectroscopy, *MOSSBAUER effect, *ASTEROIDS

Abstract

The Hayabusa2 mission sampled Ryugu, an asteroid that did not suffer extensive thermal metamorphism, and returned rocks to the Earth with no significant air exposure. It therefore offers a unique opportunity to study the redox state of carbonaceous Cb‐type asteroids and evaluate the overall redox state of the most primitive rocks of the solar system. An analytical framework was developed to investigate the iron mineralogy and valence state in extraterrestrial material at the micron scale by combining x‐ray diffraction, conventional Mössbauer (MS), and nuclear forward scattering (NFS) spectroscopies. An array of standard minerals was analyzed and cross‐calibrated between MS and NFS. Then, MS and NFS spectra on three Ryugu grains were collected at the bulk and the micron scales. In Ryugu samples, iron is essentially accommodated in magnetite, clay minerals (serpentine–smectite), and sulfides. Only a single set of Mössbauer parameters was necessary to account for the entire variability observed in MS and NFS spectra, at all spatial scales investigated. These parameters therefore make up a fully consistent iron mineralogical model for the Ryugu samples. As far as MS and NFS spectroscopies are concerned, Ryugu grains are overall similar to each other and share most of their mineralogical features with CI‐type chondrites. In detail however, no ferrihydrite is found in Ryugu particles even at the very sensitive scale of Mössbauer spectroscopy. The typical Fe3+/Fetot of clay minerals is much lower than typical redox ratios measured in CI chondrites (Fe3+/Fetot = 85%–90%). Furthermore, magnetite from Ryugu is stoichiometric with no significant maghemite component, whereas up to 12% of maghemite was previously identified in the Orgueil's so‐called magnetite. These differences suggest that most CI meteorites suffered terrestrial alteration and that the preterrestrial composition of these carbon‐rich samples was less oxidized than previously measured. However, it is not clear yet whether or not the parent bodies of CI chondrites were as reduced as Ryugu. Finally, the high spatial resolution of NFS allows to disentangle the redox state and the crystal chemistry of iron accommodated in serpentine and smectite. The most likely polytype of serpentine is lizardite, containing <35% of Fe3+, a fraction of which being tetrahedrally coordinated. Smectite is more oxidized (Fe3+/Fetot > 65%) and mainly contains octahedral ferric iron. This finding implies that these clays formed from highly alkaline fluids and the spatial variability highlighted here may suggest a temporal evolution or a spatial variability of the nature of this fluid. [ABSTRACT FROM AUTHOR]

Published

2024

43. Isotope studies of presolar silicon carbide grains from supernovae: new constraints for hydrogen-ingestion supernova models.

Author

Hoppe, Peter, Leitner, Jan, Pignatari, Marco, and Amari, Sachiko

Subjects

*SUPERNOVAE, *SILICON carbide, *ISOTOPES, *SUPERGIANT stars, *CIRCUMSTELLAR matter, *EXPLOSIVES

Abstract

We report isotope data for C, N, Al, Si, and S of 33 presolar SiC and Si3N4 grains (0.3–1.6  |$\mu$| m) of Type X, C, D, and N from the Murchison CM2 meteorite of likely core-collapse supernova (CCSN) origin which we discuss together with data of six SiC X grains from an earlier study. The isotope data are discussed in the context of hydrogen ingestion supernova (SN) models. We have modified previously used ad-hoc mixing schemes in that we considered (i) heterogeneous H ingestion into the He shell of the pre-SN star, (ii) a variable C-N fractionation for the condensation of SiC grains in the SN ejecta, and (iii) smaller mass units for better fine-tuning. With our modified ad-hoc mixing approach over small scales (0.2–0.4 M⊙), with major contributions from the O-rich O/nova zone, we find remarkably good fits (within a few per cent) for 12C/13C, 26Al/27Al, and 29Si/28Si ratios. The 14N/15N ratio of SiC grains can be well matched if variable C-N fractionation is considered. However, the Si3N4 isotope data point to overproduction of 15N in hydrogen ingestion CCSN models and lower C-N fractionation during SiC condensation than applied here. Our ad-hoc mixing approach based on current CCSN models suggests that the O-rich O/nova zone, which uniquely combines explosive H- and He-burning signatures, is favourable for SiC and Si3N4 formation. The effective range of C/O abundance variations in the He shell triggered by H ingestion events in the massive star progenitor is currently not well constrained and needs further investigation. [ABSTRACT FROM AUTHOR]

Published

2024

44. Radar observation of the new λ-Sculptorid meteor shower.

Author

Janches, D., Bruzzone, J. S., Dawkins, E. C. M., Weryk, R., Carrillo Sanchez, J. D., Egal, A., Stober, G., Hormaechea, J. L., Vida, D., and Brunini, C.

Subjects

*THERMAL equilibrium, *METEOROIDS, *METEORS, *METEOR showers, *METEORITES, *COMETS

Abstract

Context. 46P/Wirtanen is a near-Earth comet (NEC) and several previous modeling works had predicted it would produce a meteor shower for the first time on December 12, 2023. Aims. We report the most comprehensive meteor radar observations of the λ-Sculptorid meteor shower produced by comet 46P/Wirtanen. These measurements are critical to constrain the mass distribution of the particles released by the comet as radars generally detect the smaller particle population of the shower. Methods. We utilized observations with the Southern Argentina Agile Meteor Radar-Orbital System (SAAMER-OS) ideally located in the southern hemisphere to detect this shower. Since the shower was predicted to produce very slow meteors, we used the same methodology applied for the Arid meteor shower. Results. As predicted, the shower peak was observed by SAAMER-OS on December 12, 2023 (λ0 = 259.73°) at 0900 UTC, with a Zenithal Hourly Rate (ZHR) peak value of ~2.5 m h−1. Most of the activity of the shower was observed during 2 h between 0730-0930 UTC. The observed mean radiant of the shower in Sun-centered ecliptic coordinates is located at λ − λ0 = 88.9° and β = −36.6°. Our results suggest that the particles detected by SAAMER-OS are in general larger than those for which thermal equilibrium can be assumed (>3 mg) in agreement with the conclusions of previous reports using video observations. [ABSTRACT FROM AUTHOR]

Published

2024

45. Petrology, Mineralogy, and Stable Isotopic Composition of NWA 13943 (CK5) Carbonaceous Chondrite.

Author

Ao-xin, Mei and Wei-biao, Hsu

Subjects

*CARBONACEOUS chondrites (Meteorites), *ELECTRON microscope techniques, *CHONDRITES, *PROTOPLANETARY disks, *SINGLE parents, *CHROMIUM isotopes, *OXYGEN isotopes

Abstract

Karoonda-like (CK) carbonaceous chondrites are highly oxidized meteorites, with metal-to-magnetite ratio close to zero. Unlike other carbonaceous chondrites (petrologic type: 1–3), most CK chondrites have undergone thermal metamorphism (550–1270 K) on their parent body with a petrologic type 4 or above. Lines of evidence suggest a genetic relationship between CK chondrites and Vigarano-like (CV) carbonaceous chondrites, which are predominantly type 3. However, observable petrographic distinctions persist between the two groups. Thus, a thorough reevaluation of their geochemical discrepancies is critical to test the CK-CV single parent body hypothesis. Northwest Africa (NWA) 13943, a newly discovered meteorite subjected to intense modification, was classified using scanning electron microscopy and electron microprobe techniques. High-precision measurements of the mass-independent chromium isotope compositions (ε 53 Cr and ε 54 Cr) and the mass-dependent oxygen isotope compositions (δ 17 O and δ 18 O) of NWA 13943 were reported for the first time. Integrating petrological, mineralogical, oxygen, and chromium isotopic data, it is legitimated to infer that CK and CV chondrites may originate from two proximal but distinct isotopic reservoirs within the protoplanetary disk. [ABSTRACT FROM AUTHOR]

Published

2024

46. Potential of synchrotron X-ray diffraction computed tomography (XRDCT) for a 3D non-destructive and/or non-invasive characterisation of cultural heritage geomaterials (CHG).

Author

Possenti, Elena, Catrambone, Maria, Colombo, Chiara, Cantaluppi, Marco, Merlini, Marco, Vaughan, Gavin B.M., di Michiel, Marco, and Marinoni, Nicoletta

Subjects

*COMPUTED tomography, *THREE-dimensional imaging, *SYNCHROTRON radiation, *CULTURAL property, *STONE

Abstract

• XRDCT is used to characterise unique multiphase cultural heritage geomaterials (CHG). • 3D mapping of crystalline phases is carried out non-destructively or non-invasively. • Qualitative/quantitative phase analysis and 3D imaging are simultaneously performed. • Potential and limits of XRDCT for new CHG applications are critically discussed. • New analytical perspectives in the characterisation of heterogeneous CHG are proposed. The present work describes the high potential of the recently developed synchrotron X-ray diffraction computed tomography (XRDCT) for 3D mapping of crystalline and amorphous phases in Geomaterials of Cultural Heritage (CHG). The paper critically discusses the promising results and limitations of XRDCT in Cultural Heritage applications. XRDCT has been applied herein to diverse CHG materials, spanning from archaeological ceramics, and stone conservation treatments to meteorites, at a microscale. Although these materials are very complex systems from a chemical, mineralogical and microstructural point of view, this innovative technique proves effective capability to access the real spatial distribution and semi-quantification of crystallographic phases within materials in a totally non-destructive and/or non-invasive way. [ABSTRACT FROM AUTHOR]

Published

2024

47. The Ordovician meteorite event in North America: Age of the Slate Islands impact structure, northern Lake Superior, Ontario, Canada.

Author

Parisi, Andrew F., Catlos, Elizabeth J., Brookfield, Michael E., Schmitt, Axel K., Stöckli, Daniel F., Miggins, Daniel P., and Campos, Daniel S.

Subjects

*METEORITES, *PLAGIOCLASE, *ZIRCON, *URANIUM-lead dating, *NEOARCHAEAN

Abstract

The Slate Islands (Ontario) is one of Canada's larger impact structures at 32 km in diameter and has been linked to the Ordovician meteorite event (OME). We report zircon U–Pb dates from two suevite and two syenite samples collected from the Slate Islands. Plagioclase 40Ar/39Ar dates were also obtained from one of the samples. The plagioclase and most zircon dates record pre‐impact ages with links to known tectonic events, including those associated with the assembly of the Superior Craton at approximately 2700 Ma. However, Neoarchean zircon grains appear to be reset at 456.1 ± 6.9 Ma (±2σ) based on the lower intercept of discordia for all dated samples. The date overlaps its previously accepted age of 450 Ma and would be 2–19 million years following the parent asteroid breakup if related to the OME. [ABSTRACT FROM AUTHOR]

Published

2024

48. The Meteoritical Bulletin, no. 112.

Author

Gattacceca, Jérôme, M c Cubbin, Francis M., Grossman, Jeffrey N., Schrader, Devin L., Cartier, Camille, Consolmagno, Guy, Goodrich, Cyrena, Greshake, Ansgar, Gross, Juliane, Joy, Katherine Helen, Miao, Bingkui, and Zhang, Bidong

Subjects

*IRON meteorites, *CHONDRITES, *ACHONDRITES, *METEORITES, *ENSTATITE, *MARTIAN meteorites

Abstract

Meteoritical Bulletin 112 contains the 2487 meteorites approved by the Nomenclature Committee of the Meteoritical Society in 2023. It includes 14 falls, 1926 ordinary chondrites, 141 HED, 127 carbonaceous chondrites (including 6 ungrouped), 71 lunar meteorites, 37 ureilites, 36 mesosiderites, 27 Martian meteorites, 23 iron meteorites (6 ungrouped), 20 Rumuruti chondrites, 19 ungrouped achondrites, 19 enstatite chondrites, 18 primitive achondrites (2 ungrouped), 12 pallasites, 6 angrites, 4 enstatite achondrites, and 1 ungrouped chondrite. Of the meteorites approved in 2023, 968 were from Africa, 836 from South America, 572 from Antarctica, 66 from Asia, 35 from North America, 9 from Europe, and 1 from Oceania. [ABSTRACT FROM AUTHOR]

Published

2024

49. The fireball of November 24, 1970, as the most probable source of the Ischgl meteorite.

Author

Gritsevich, Maria, Moilanen, Jarmo, Visuri, Jaakko, Meier, Matthias M. M., Maden, Colin, Oberst, Jürgen, Heinlein, Dieter, Flohrer, Joachim, Castro‐Tirado, Alberto J., Delgado‐García, Jorge, Koeberl, Christian, Ferrière, Ludovic, Brandstätter, Franz, Povinec, Pavel P., Sýkora, Ivan, and Schweidler, Florian

Subjects

*METEORITES, *ORBITS (Astronomy), *RADIOISOTOPES, *METEOROIDS, *METEORS, *CAMERAS, *AVALANCHES, *WEATHERING

Abstract

The discovery of the Ischgl meteorite unfolded in a captivating manner. In June 1976, a pristine meteorite stone weighing approximately 1 kg, fully covered with a fresh black fusion crust, was collected on a mountain road in the high‐altitude Alpine environment. The recovery took place while clearing the remnants of a snow avalanche, 2 km northwest of the town of Ischgl in Austria. Subsequent to its retrieval, the specimen remained tucked away in the finder's private residence without undergoing any scientific examination or identification until 2008, when it was brought to the University of Innsbruck. Upon evaluation, the sample was classified as a well‐preserved LL6 chondrite, with a W0 weathering grade, implying a relatively short time between the meteorite fall and its retrieval. To investigate the potential connection between the Ischgl meteorite and a recorded fireball event, we have reviewed all documented fireballs ever photographed by German fireball camera stations. This examination led us to identify the fireball EN241170 observed in Germany by 10 different European Network stations on the night of November 23/24, 1970, as the most likely candidate. We employed state‐of‐the‐art techniques to reconstruct the fireball's trajectory and to reproduce both its luminous and dark flight phases in detail. We find that the determined strewn field and the generated heat map closely align with the recovery location of the Ischgl meteorite. Furthermore, the measured radionuclide data reported here indicate that the pre‐atmospheric size of the Ischgl meteoroid is consistent with the mass estimate inferred from our deceleration analysis along the trajectory. Our findings strongly support the conclusion that the Ischgl meteorite originated from the EN241170 fireball, effectively establishing it as a confirmed meteorite fall. This discovery enables to determine, along with the physical properties, also the heliocentric orbit and cosmic history of the Ischgl meteorite. [ABSTRACT FROM AUTHOR]

Published

2024

50. Low‐temperature thermal and physical properties of lunar meteorites.

Author

Macke, R. J., Opeil, C. P., Britt, D. T., Consolmagno, G. J., and Irving, A.

Subjects

*THERMAL properties, *METEORITES, *HEAT capacity, *LUNAR surface, *THERMAL conductivity, *THERMAL diffusivity

Abstract

Lunar meteorites are the most diverse and readily available specimens for the direct laboratory study of lunar surface materials. In addition to informing us about the composition and heterogeneity of lunar material, measurements of their thermo‐physical properties provide data necessary to inform the models of the thermal evolution of the lunar surface and provide data on fundamental physical properties of the surface material for the design of exploration and resource extraction hardware. Low‐temperature data are particularly important for the exploration of low‐temperature environments of the lunar poles and permanently shadowed regions. We report low‐temperature‐specific heat capacity, thermal conductivity, and linear thermal expansion for six lunar meteorites: Northwest Africa [NWA] 5000, NWA 6950, NWA 8687, NWA 10678, NWA 11421, and NWA 11474, over the range 5 ≤ T ≤ 300 K. From these, we calculate thermal inertia and thermal diffusivity as functions of temperature. Additionally, heat capacities were measured for 15 other lunar meteorites, from which we calculate their Debye temperature and effective molar mass. [ABSTRACT FROM AUTHOR]

Published

2024