¹Brittany A. Cymes,²Katherine D. Burgess,^3,4Noah Jäggi,³André Galli,⁵Herbert Biber,⁵Johannes Brötzner,⁶Paul S. Szabo,⁷Andreas Nenning,⁵Friedrich Aumayr
The Planetary Science Journal 7, 6 Open Access Link to Article [DOI 10.3847/PSJ/ae2657]

¹Amentum, NASA Johnson Space Center, 2101 E. NASA Parkway, Houston, TX 77058, USA
²Materials Science and Technology Division, U.S. Naval Research Laboratory, 4555 Overlook Avenue SW, Washington, DC 20375, USA
³Space Research and Planetary Sciences, Physics Institute, University of Bern, Sidlerstrasse 5, 3012 Bern, Switzerland
⁴Laboratory for Astrophysics and Surface Physics, University of Virginia, 395 McCormick Road, Charlottesville, VA 22904, USA
⁵Institute of Applied Physics, TU Wien, Wiedner Hauptstraße 8-10, 1040, Vienna, Austria
⁶Space Sciences Laboratory, University of California, 7 Gauss Way, Berkeley, CA 94720, USA
⁷Institute of Chemical Technologies and Analytics, TU Wien, Getreidemarkt 9, 1060, Vienna, Austria

We currently do not have a copyright agreement with this publisher and cannot display the abstract here

¹Addi Bischoff et al. (>10)
Meteoritics & Planetary Science (in Press) Open Access Link to Article [https://doi.org/10.1111/maps.70106]
¹Institut für Planetologie, University of Münster, Münster, Germany
Published by arrangement with John Wiley & Sons

On Tuesday, February 18, 2025, at 18:04:14 local time, residents of Poland observed a bright fireball registered by many Polish fireball stations belonging to the Skytinel Network established a few months before by Mateusz Żmija. Thus, the meteoroid’s orbit, atmospheric trajectory, and the strewn field were calculated, and over 70 fragments with a mass of approximately 3900 g were found near Drelów (Lublin Voivodeship, Poland; The Meteorite Bulletin Database, 2025). The samples were recovered by scientists, private searchers, and dealers, and many samples were offered immediately for collections and scientific research on the international meteorite market. Drelów is the 13th officially registered meteorite fall in Poland and is now officially classified as an L6 ordinary chondrite (S3, W0; The Meteorite Bulletin Database, 2025). Short-lived radionuclides were measured on a small sample shortly after recovery, and the results confirm that the meteorite specimen studied here derived from the bolide fireball event. The equilibrated and recrystallized type 6 character is also supported by the large plagioclase grains (An9-12; with grains >100 μm) and the homogeneous compositions of olivine (Fa24.7±0.4) and low-Ca pyroxene (Fs20.8±0.3). The olivine in Drelów is dominated by grains with planar fractures, but in the Münster samples a significant fraction of olivine shows weak mosaicism, indicating a moderately shocked S4 (C-S4) chondritic rock. Such mosaic olivine grains appear to lack in other fragments of Drelów requiring a S3 (C-S3) classification. Thus, Drelów experienced an equilibrium shock pressure close to the strength that defines the S3/S4 transition, which requires an equilibrium shock pressure of slightly above 20 GPa. The meteorite shows easily visible dark shock veins that cross-cut the bulk rock; the high-pressure phases maskelynite and wadsleyite were detected within or close to the veins. The O isotope data and the bulk chemical composition are consistent with the L-group membership. This is also confirmed by the density and the magnetic susceptibility measurements. The soluble organic compositions of Drelów are consistent with the profiles of unbrecciated L6 chondrites and comparable to Braunschweig (L6), showing molecular characteristics consistent with the complex shock and metamorphic history of the parent rock.

¹Sam Uthup, ¹J. Gregory Shellnutt
Icarus (in Press) Link to Article [https://doi.org/10.1016/j.icarus.2026.116985]

¹Department of Earth Science, National Taiwan Normal University, 88 Tingzhou Road Section 4, Taipei 11677, Taiwan
Copyright Elsevier

Venus is a telluric planet with similar size, composition, and mass to that of the Earth. The Venusian crust is mainly divided into lowland (~80%) and highland regions (~10%) based on their surface elevation. The lowland regions are characterized by featureless lava plains, whereas the highlands consist of crustal plateaux, tesserae terrane, and volcanic troughs. The presence of evolved silicic igneous rocks in the highland regions of the Venus has been debated. In this study, phase equilibria modelling using THERMOCALC and the basaltic compositions obtained from the Venera 14 and Vega 2 lander missions are employed to estimate partial melt compositions in both hydrous and anhydrous conditions. Hydrous partial melting of the Venera 14 composition generated tonalitic-trondhjemite-granodiorite- (TTG) melts at shallow crustal depths with 5% partial melting. The Vega 2 composition could also generate TTG like melts in hydrous conditions, but at a slightly higher-pressure (~5 kbar). However, anhydrous partial melting modelling results were unable to generate a TTG-like melts. The results of THERMOCALC modelling indicate that TTG-like melts can be generated in the crust from the basaltic compositions of Venera 14 and Vega 2 by hydrous partial melting. The implication is that the highland regions of Venus may be an ideal location to search for silicic rocks that are typical of terrestrial Archean crust.

¹Ashley Rogers,^1,2Lucy Forman,³Kai Rankenburg,^1,4Rachel Kirby,³Martin Danišík,¹Victoria Cousins,^1,2,5Gretchen K. Benedix
Meteoritics & Planetary Science (in Press) Open Access Link to Article [https://doi.org/10.1111/maps.70101]
¹Space Science and Technology Centre, School of Earth and Planetary Science, Curtin University, Perth, Western Australia,Australia
²Department of Minerals & Meteorites, Western Australian Museum, Perth, Western Australia, Australia
³John de Laeter Centre, Curtin University, Perth, Western Australia, Australia
⁴School of Earth, Atmosphere and Environment, Monash University, Melbourne, Victoria, Australia
⁵Planetary Science Institute, Tucson, Arizona, USA
Published by arrangement with John Wiley & Sons

Under the current classification scheme, ungrouped irons make up ~11% of all recognized iron meteorites. A further ~7% of iron meteorites are currently classified as simply “irons” and are yet to be fully classified. To potentially classify these meteorites, newer approaches, including either statistical modeling or advanced geochemical/petrological characterization, may be required. To approach this issue, we studied three ungrouped iron meteorites from Western Australia—Pennyweight, Prospector Pool, and Redfields. We conducted petrographical and geochemical analyses using a TESCAN Integrated Mineral Analyzer (TIMA), electron backscattered diffraction (EBSD), and laser ablation inductively coupled mass spectrometry (LA-ICP-MS). Through these analyses, the modal abundances, orientation relationships, and geochemical properties of the key metallic phases were determined. From this work, we have found that spot analyses of the kamacite and plessite are sufficient for iron meteorite classification, and these values can be used to reconstruct a “bulk” geochemical composition. Additionally, statistical data reduction (principal component analysis and t-distributed stochastic neighbor embedding) models have been used, in conjunction with the traditional logarithmic element plots, to assist with classification. Our results agree with previous studies that recommend the reclassification of Prospector Pool to the IIE group. Pennyweight may be a mesosiderite metal nodule with a metal composition closer to the IIIAB and IIE meteorites but has petrographical features similar to the IIE irons. It should remain ungrouped at this stage. Redfields is most likely a member of the IAB complex, potentially an IAB anomalous meteorite. Finally, the statistical models show a dichotomy between the IAB group and that the current iron meteorite groups seem to have more geochemical similarities than differences. Further analysis is required to assess the validity of the current classification scheme.

^1,2Lauren A. Jennings, ¹Stephan Klemme, ³Max Collinet, ²Julia Maia, ^1,2Carianna Herrera, ²Ana-Catalina Plesa
Icarus (in Press) Open Access Link to Article [https://doi.org/10.1016/j.icarus.2026.116986]
¹Institut für Mineralogie, Universität Münster, Corrensstraße 24, Münster 48149, Germany
²Institute of Space Research, German Aerospace Center (DLR), Berlin, Germany
³Institute of Life, Earth and Environment, Geology Department, University of Namur, Namur, Belgium
Copyright Elsevier

The mantle composition of Venus is often assumed to be similar to Earth, albeit with a lower iron content to account for the density differences between the two planets. However, it has yet to be tested whether partial melting of proposed Venusian mantle compositions can produce melts that are similar to the measured basaltic rock compositions analysed in-situ during the Venera 14 and Vega 2 missions. In this study, we used Perple_X to calculate melt compositions from several bulk mantle compositions of Venus and found they were unable to reliably produce primary melt compositions that are similar to the Venera 14 or Vega 2 basalts, regardless of the oxidation state or degree of fractional crystallisation. As such, we used an iterative approach to identify new mantle compositions for Venus that are able to produce Vega 2- and/or Venera 14-like melts over a large pressure and temperature range. We found 23 mantle compositions that are similar to the terrestrial composition of KLB-1, but have a high Al2O3 and low CaO abundance, resulting in a sub-chondritic CaO/Al2O3 and SiO2/Al2O3. We recommend two of these as new mantle compositions for Venus as they were the most successful at producing Venus-like melts. Lastly, we propose that the sub-chondritic ratios of these new mantle compositions are the result of igneous processes, such as magma ocean differentiation and Ca-rich carbonatite melt extraction, that altered the mantle composition prior to the melting that produced the basalts sampled by the Venera 14 and Vega 2 missions.

¹M.C. Benner, ^1,2T.J. Zega, ¹B.S. Prince, ³Z.E. Wilbur,^1,4,5H.C. Connolly Jr., ¹D.S. Lauretta
Geochimica et Cosmochimica Acta (in Press) Open Access Link to Article [https://doi.org/10.1016/j.gca.2026.01.056]
¹Lunar and Planetary Laboratory, University of Arizona, Tucson, AZ, USA
²Department of Materials Science & Engineering, University of Arizona, Tucson, AZ, USA
³Department of Mineral Sciences, National Museum of Natural History, Smithsonian Institution, Washington, DC, USA
⁴Department of Geology, Rowan University, Glassboro, NJ, USA
⁵Department of Earth and Planetary Science, American Museum of Natural History, New York, NY, USA
Copyright Elsevier

We report the discovery of fibrous mackinawite in samples of asteroid Bennu returned by the OSIRIS-REx mission. Mackinawite occurs primarily in particles belonging to Bennu’s hummocky lithology, with fibers that range from 75 to 250 nm in length and 10 to 30 nm in width. In Bennu particles, mackinawite displays both fibrous and tabular habits and forms flower-like clusters that resemble the texture of coarse-grained phyllosilicates previously described. Energy-dispersive X-ray spectroscopy indicates an Fe/S ratio of 1, and four-dimensional scanning transmission electron microscopy reveals a tetragonal structure consistent with mackinawite. Similar to terrestrial occurrences, the activities of Fe2+ and S2– in aqueous solution are likely the main drivers of mackinawite precipitation within Bennu’s parent body. We suggest that mackinawite formed via precipitation from solution following the dissolution of accreted metal and sulfides when Fe and S activities were high enough to support mackinawite stability. Based on comparison to terrestrial Pourbaix diagrams, we hypothesize that mackinawite precipitation within Bennu’s parent body was possible at 7 < pH < 10, –0.5 < Eh < –0.15, 10–9 ≤ aFe ≤ 10–6, and temperatures up to 70°C.

¹Jintuan Wang, ²Hongluo L. Zhang, ¹Le Zhang, ¹Yonghua Cao, ²Zhendun Qi, ¹Pengli He, ¹Mang Lin,¹Yi-Gang Xu
Geochimica et Cosmochimica Acta (in Press) Link to Article [https://doi.org/10.1016/j.gca.2026.01.046]
¹State Key Laboratory of Deep Earth Processes and Resources, Guangzhou Institute of Geochemistry, Chinese Academy of Sciences, Guangzhou 510640, China
²State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Beijing 100083, China
Copyright Elsevier

Lunar basalts are much more reduced than their terrestrial counterparts and exhibit more than three orders of magnitude variability in oxygen fugacity (fO2). However, the origin of this large fO2 variation remains enigmatic. The Chang’e-5 (CE-5) basalt, derived from a pyroxene-bearing mantle source, provides a unprecedented opportunity to decipher the redox variation of lunar samples. The mineral/melt partitioning behaviors of vanadium (V) and europium (Eu) are sensitive to fO2, and thus capable of evaluating the fO2 of rocks. However, previous oxybarometers based on the partitioning behaviours of V and Eu are not applicable to CE-5 basalt due to the difference in composition and formation P−T conditions. Here we performed experiments at 1120−1140 °C and fO2 range of IW −1.2 to IW+3.3 (IW, iron-wüstite buffer) on a synthesized CE-5 whole rock (WR) composition and calibrated oxybarometers (olivine/melt and spinel/melt V and plagioclase/melt Eu partitioning) pertinent to the CE-5 lunar basalt. Applying the calibrated oxybarometers to CE-5 basalt, we estimated the fO2 of the CE-5 basalt to be
, which is generally more oxidized than most lunar basalts. To further investigate the cause for the high fO2 of CE-5 basalt, we performed crystallization modeling of the lunar magma ocean. The results reveal that the lunar mantle is stratified with Fe3+/FeT and fO2, with the shallower regions being more oxidized, suggesting that the oxidized nature of CE-5 basalt likely induced by the involvement of oxidized shallow mantle reservoirs. Moreover, the results found a unified framework to explain the large fO2 variation in lunar samples.

^1,2Alexander A. NEMCHIN,³Marc D. NORMAN,⁴Martin J. WHITEHOUSE,⁵Evgenia SALIN,²Nicholas E. TIMMS,⁶Tao LONG,⁶Xiaochao CHE,⁷Renaud MERLE,²Fred JOURDAN,⁸Tao LUO
Meteoritics & Planetary Science (in Press) Open Access Link to Article [https://doi.org/10.1111/maps.70103]
¹School of Earth Sciences and Engineering, Nanjing University, Nanjing, China
²Space Science and Technology Centre, School of Earth and Planetary Sciences, Curtin University, Perth, Western Australia,Australia
³Research School of Earth Sciences, The Australian National University, Canberra, Australian Capital Territory, Australia
⁴Department of Geosciences, Swedish Museum of Natural History, Stockholm, Sweden
⁵Department of Geology and Mineralogy, ˚Abo Akademi University, Turku, Finland
⁶Beijing SHRIMP Center, Institute of Geology, Chinese Academy of Geological Sciences, Beijing, China
⁷Department of Earth Sciences, Uppsala University, Uppsala, Sweden
⁸State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan, China
Published by arrangement with John Wiley & Sons

Rapidly quenched droplets of pyroclastically erupted lava are common in lunar regolith at landing sites proximal to the maria. Here, we document the U-Pb chronologies, major element, and trace element compositions of picritic glassy particles from Apollo 17 regolith sample 76501. These particles are dominated by high-Ti compositions similar to those of the established Apollo 17 orange and black pyroclastic deposits, but the textures of some beads indicate slower cooling and/or equilibration at lower temperatures. Using a new approach to calibrate SIMS U-Pb isotopic analysis of vitrophyric beads, we show that their U-Pb ages are consistent with a single or closely timed multiple eruptions ~50–100 Ma younger than the 3752 ± 9 to 3758 ± 12 Ma crystalline mare basalts collected at this site. A few picritic beads with very low-Ti compositions may be younger, but their ages are not well defined and can be ~3.3–3.6 Ga.

¹Sophie Benaroya,¹Christopher D. K. Herd,¹David T. Flannery,¹Nicolas Randazzo
Meteoritics & Planetary Science (in Press) Open Access Link to Article [https://doi.org/10.1111/maps.70104]
¹Department of Earth and Atmospheric Sciences, University of Alberta, Edmonton, Alberta, Canada
²School of Earth and Atmospheric Sciences, Queensland University of Technology, Brisbane, Queensland, Australia
Published by arrangement with John Wiley & Sons

Mars Sample Return (MSR) is expected to transform planetary science by providingunprecedented access to pristine Martian material. Initial characterization in the samplereceiving facility (SRF) will rely on nondestructive techniques such as X-ray computedtomography (XCT) to document the condition, distribution, and internal features of sealedcore samples. To test XCT protocols in advance of MSR, we analyzed terrestrial analog corescollected during the Pilbara Sample Return campaign in Western Australia. Sedimentary andregolith samples were scanned at both whole-core and fragment scales to evaluate scan times,optimal energy conditions, and resolution limits. Our results demonstrate that XCT offerscritical insights into fragment size distributions, internal banding, porosity, and fracturenetworks before sample opening, information that is essential for subsampling and preservingastrobiologically relevant textures. Integration with Raman spectroscopy, optical microscopy,and EPMA confirmed that XCT reliably identifies high-attenuation (high-l) phases (e.g.,oxides, sulfides) but cannot distinguish between common silicates, underscoring the need formulti-modal characterization. We also demonstrate how XCT data sets can be used to tracksample mass, restore fragment orientation, and potentially reconstruct stratigraphic context.Updated sample mass estimates indicate that the MSR collection is sufficient to meetcommunity science objectives, with required masses (12–15 g per core) well below expectedreturns. These results highlight XCT as a cornerstone of SRF pre-basic characterization,providing both immediate triage value and a foundation for long-term digital curation.

^1,2Julia Neukampf, ²Yves Marrocchi, ²Johan Villeneuve, ³Mathieu Roskosz
Geochimica et Cosmochimica Acta (in Press) Open Access Link to Article [https://doi.org/10.1016/j.gca.2026.01.041]
¹The University of Manchester, Oxford Road, M13 9PL Manchester, UK
²Université de Lorraine, CNRS, CRPG F-54000 Nancy, France
³Institut de Minéralogie, de Physique des Matériaux et de Cosmochimie (IMPMC), Muséum national d’Histoire naturelle, Sorbonne Université, CNRS, F- 75005 Paris, France
Copyright Elsevier

We report high-precision lithium (Li) abundances and isotopic compositions of olivine crystals from type I chondrules in carbonaceous chondrites (Murchison, NWA 852, Renazzo) and type II chondrules in ordinary chondrites (NWA 11752, NWA 12462, NWA 12581, NWA 13501). Olivine crystals in type I chondrules exhibit large Li isotopic fractionations both within and between grains, with δ⁷Li values ranging from −46.6‰ to + 9.9‰ and Li concentrations of 3.8–9.0 ppm. Olivine grains in type II chondrules, including Mg-rich relict cores, show δ⁷Li values from −38.0‰ to + 8.4‰ (Li = 0.6–5.6 ppm), while their Fe-rich overgrowths exhibit lower variability, with δ⁷Li values between −30.6‰ and + 4.7‰ (Li = 0.6–11.9 ppm). Our data indicate that the observed variations are not attributable to low-temperature aqueous alteration or dry thermal metamorphism, fractional crystallisation, or simple degassing of the chondrule melt. Instead, the Li isotopic signatures are best explained by kinetic fractionation during open-system gas–melt exchange with a volatile-rich vapour, enriching the chondrule melts in Li. Such open-system processes produced larger isotopic fractionations than expected during closed-system crystallisation. These findings suggest that some type II chondrules may have originated from type I chondrules through reprocessing in an open-system environment, providing new insights into the complex physicochemical evolution of early solar system solids.