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1. Role of Oxygen Fugacity on the Melting Properties of Enstatite Chondrites and Implications for Mercury’s Magmatic Evolution

Author

R. Gwyn, T. McCombs, S. Lambart, K. Righter, L. R. Nittler, and A. Boujibar

Subjects
Lunar and Planetary Science and Exploration
Abstract

Mercury, the innermost terrestrial planet, is the most reduced planet in our solar system. Insights from MESSENGER mission data revealed the presence of several distinct geochemical terranes, evidence of complex magmatic processes and collisional processes exposing subsurface materials. Surface chemical analysis indicated elevated S (~2-3 wt%) and low FeO (~1.5 wt%) concentrations. The high sulfur concentration indicates reduced conditions with an average of 5.4 log units below the Iron-Wüstite (IW) oxygen fugacity (O2) buffer (IW-5.4). Surface compositions also show a range in redox conditions during mantle melting and eruption, with inferred log fO2, ranging from IW-6.5 to IW-3.5. The effects of oxygen fugacity on magmatic differentiation are poorly constrained, despite their significance in our understanding of mantle-crust differentiation in the solar system. Enstatite High-Fe (EH) chondrites are very reduced undifferentiated meteorites with elevated concentrations of Fe and volatiles like S, Cl, Na, and K as compared to other chondrites. These characteristics suggest that EH chondrites are a potential analog for Mercury’s building blocks. However, the comparison of Mercury’s surface composition with melting products of EH chondrites is necessary to determine whether Mercury surface materials may be derived from EH chondrite- like materials. Here, we investigate the role of fO2 on EH melting properties and its implications for Mercury’s accretion and differentiation.

Published
2024

4. The future of Stardust science

Author

A. J. Westphal, J. C. Bridges, D. E. Brownlee, A. L. Butterworth, B. T. De Gregorio, G. Dominguez, G. J. Flynn, Z. Gainsforth, H. A. Ishii, D. Joswiak, L. R. Nittler, R. C. Ogliore, R. Palma, R. O. Pepin, T. Stephan, and M. E. Zolensky

Published
2017
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7. Organic synthesis associated with serpentinization and carbonation on early Mars

Author

A. Steele, L. G. Benning, R. Wirth, A. Schreiber, T. Araki, F. M. McCubbin, M. D. Fries, L. R. Nittler, J. Wang, L. J. Hallis, P. G. Conrad, C. Conley, S. Vitale, A. C. O’Brien, V. Riggi, and K. Rogers

Subjects
Multidisciplinary
Abstract

Abiotic formation of organic molecules Mars rovers have found complex organic molecules in the ancient rocks exposed on the planet’s surface and methane in the modern atmosphere. It is unclear what processes produced these organics, with proposals including both biotic and abiotic sources. Steele et al . analyzed the nanoscale mineralogy of the Mars meteorite ALH 84001 and found evidence of organic synthesis driven by serpentinization and carbonation reactions that occurred during the aqueous alteration of basalt rock by hydrothermal fluids. The results demonstrate that abiotic production of organic molecules operated on Mars 4 billion years ago. —KTS

Published
2022

9. Interplanetary and interstellar dust as windows into solar system origins and evolution

Author

Veerle Sterken, F. Postrberg, Julie Castillo-Rogez, Zoltan Sternovsky, L. R. Nittler, Eberhard Grün, Andrew R. Poppe, Rhonda M. Stroud, Conel M. O'd. Alexander, J. R. Szalay, Neal J. Turner, Marc Fries, Sascha Kempf, Z. Hu, Thomas Stephan, Tibor S. Balint, Jon K. Hillier, Tobin Munsat, Mihaly Horanyi, Diane H. Wooden, David Nesvorný, Petr Pokorný, Hope A. Ishii, Amara Graps, Bruce T. Draine, R. Sarama, Andrew J. Westphal, Cécile Engrand, M. Lugaro, S. Merouane, Laboratoire de Physique des 2 Infinis Irène Joliot-Curie (IJCLab), and Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)

Subjects
Physics, Solar System, [SDU]Sciences of the Universe [physics], Interplanetary spaceflight, ComputingMilieux_MISCELLANEOUS, Cosmic dust, Astrobiology
Abstract

International audience

Published
2021

10. The nature, origin and modification of insoluble organic matter in chondrites, the possibly interstellar source of Earth's C and N

Author

C M O'D, Alexander, G D, Cody, B T, De Gregorio, L R, Nittler, and R M, Stroud

Subjects
Article
Abstract

All chondrites accreted ~3.5 wt.% C in their matrices, the bulk of which was in a macromolecular solvent and acid insoluble organic material (IOM). Similar material to IOM is found in interplanetary dust particles (IDPs) and comets. The IOM accounts for almost all of the C and N in chondrites, and a significant fraction of the H. Chondrites and, to a lesser extent, comets were probably the major sources of volatiles for the Earth and the other terrestrial planets. Hence, IOM was both the major source of Earth’s volatiles and a potential source of complex prebiotic molecules. Large enrichments in D and (15)N, relative to the bulk solar isotopic compositions, suggest that IOM or its precursors formed in very cold, radiation-rich environments. Whether these environments were in the interstellar medium (ISM) or the outer Solar System is unresolved. Nevertheless, the elemental and isotopic compositions and functional group chemistry of IOM provide important clues to the origin(s) of organic matter in protoplanetary disks. IOM is modified relatively easily by thermal and aqueous processes, so that it can also be used to constrain the conditions in the solar nebula prior to chondrite accretion and the conditions in the chondrite parent bodies after accretion. Here we review what is known about the abundances, compositions and physical nature of IOM in the most primitive chondrites. We also discuss how the IOM has been modified by thermal metamorphism and aqueous alteration in the chondrite parent bodies, and how these changes may be used both as petrologic indicators of the intensity of parent body processing and as tools for classification. Finally, we critically assess the various proposed mechanisms for the formation of IOM in the ISM or Solar System.

Published
2019

12. Identification of Rare Polytypes of Presolar SiC with Coordinated TEM, Raman Spectroscopy and NanoSIMS Measurements

Author

Rhonda M. Stroud, Bradley T. De Gregorio, C. M. O'd. Alexander, Andrew Steele, Nan Liu, and L. R. Nittler

Subjects
symbols.namesake, Materials science, 0103 physical sciences, symbols, Analytical chemistry, Identification (biology), 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, Raman spectroscopy, 010303 astronomy & astrophysics, 01 natural sciences, Instrumentation
Published
2017

14. Non-destructive search for interstellar dust using synchrotron microprobes

Author

A. J. Westphal, A. Allbrink, C. Allen, S. Bajt, R. Bastien, H. Bechtel, P. Bleuet, J. Borg, S. Bowker, F. Brenker, J. Bridges, D. E. Brownlee, M. Burchell, M. Burghammer, A. L. Butterworth, A. Campanile, P. Cloetens, G. Cody, T. Ferroir, K. Ferrari, C. Floss, G. J. Flynn, D. Frank, Z. Gainsforth, E. Grün, M. Harmer, P. Hoppe, A. Kearsley, S. Kulkarni, B. Lai, L. Lemelle, H. Leroux, R. Lettieri, W. Marchant, B. McCreadie, L. R. Nittler, R. Ogliore, F. Postberg, C. Rigamonti, S. A. Sandford, S. Schmitz, G. Silversmit, A. Simionovici, G. Sperry, R. Srama, F. Stadermann, T. Stephan, R. M. Stroud, J. Susini, S. Sutton, V. Thompson, R. Toucoulou, M. Trieloff, P. Tsou, A. Tsuchiyama, T. Tyliczszak, B. Vekemans, L. Vincze, J. Warren, T. Yahnke, D. Zevin, M. E. Zolensky, Melissa Denecke, and Clive T. Walker

Subjects
Interstellar medium, Physics, X-ray spectroscopy, Beamline, law, Infrared, X-ray fluorescence, Infrared cirrus, Astrophysics, Synchrotron, law.invention, Cosmic dust
Abstract

Here we describe the critical role that synchrotron X-ray and infrared microprobes are playing in the search for interstellar dust in the Stardust Interstellar Dust Collector (SIDC). The samples under examination are submicron particles trapped in low-density aerogel. We have found that the spatial resolution, energy range, and flux capabilities of the FTIR beamlines 1.4.3, ALS, and U2B, NSLS; the XRF microprobes ID13 and ID22NI, ESRF and 2-ID-D, APS; and the STXM beamline 11.0.2, ALS are ideally suited for studying these tiny returned samples. Using nondestructive, coordinated analyses at these microprobes, we have been able to eliminate most candidates as likely samples of interstellar dust. This in itself is a major accomplishment, since the analysis of these tiny samples is technically extremely challenging.

Published
2010

15. Focused Ion Beam Slice-and-View Tomography and Correlative Electron Microscopy of Multiphase Meteorite Particles

Author

Keana C. Scott, C.D. Herd, Nabil Bassim, Rhonda M. Stroud, and L. R. Nittler

Subjects
Correlative, Materials science, business.industry, Analytical chemistry, Focused ion beam, law.invention, Optics, Meteorite, law, Wafer, Tomography, Electron microscope, business, Instrumentation
Abstract

Extended abstract of a paper presented at Microscopy and Microanalysis 2013 in Indianapolis, Indiana, USA, August 4 – August 8, 2013.

Published
2013

16. Pebbles and sand on asteroid (162173) Ryugu: In situ observation and particles returned to Earth

Author

S. Tachibana, H. Sawada, R. Okazaki, Y. Takano, K. Sakamoto, Y. N. Miura, C. Okamoto, H. Yano, S. Yamanouchi, P. Michel, Y. Zhang, S. Schwartz, F. Thuillet, H. Yurimoto, T. Nakamura, T. Noguchi, H. Yabuta, H. Naraoka, A. Tsuchiyama, N. Imae, K. Kurosawa, A. M. Nakamura, K. Ogawa, S. Sugita, T. Morota, R. Honda, S. Kameda, E. Tatsumi, Y. Cho, K. Yoshioka, Y. Yokota, M. Hayakawa, M. Matsuoka, N. Sakatani, M. Yamada, T. Kouyama, H. Suzuki, C. Honda, T. Yoshimitsu, T. Kubota, H. Demura, T. Yada, M. Nishimura, K. Yogata, A. Nakato, M. Yoshitake, A. I. Suzuki, S. Furuya, K. Hatakeda, A. Miyazaki, K. Kumagai, T. Okada, M. Abe, T. Usui, T. R. Ireland, M. Fujimoto, T. Yamada, M. Arakawa, H. C. Connolly, A. Fujii, S. Hasegawa, N. Hirata, C. Hirose, S. Hosoda, Y. Iijima, H. Ikeda, M. Ishiguro, Y. Ishihara, T. Iwata, S. Kikuchi, K. Kitazato, D. S. Lauretta, G. Libourel, B. Marty, K. Matsumoto, T. Michikami, Y. Mimasu, A. Miura, O. Mori, K. Nakamura-Messenger, N. Namiki, A. N. Nguyen, L. R. Nittler, H. Noda, R. Noguchi, N. Ogawa, G. Ono, M. Ozaki, H. Senshu, T. Shimada, Y. Shimaki, K. Shirai, S. Soldini, T. Takahashi, Y. Takei, H. Takeuchi, R. Tsukizaki, K. Wada, Y. Yamamoto, K. Yoshikawa, K. Yumoto, M. E. Zolensky, S. Nakazawa, F. Terui, S. Tanaka, T. Saiki, M. Yoshikawa, S. Watanabe, and Y. Tsuda

Subjects
Multidisciplinary
Abstract

The Hayabusa2 spacecraft investigated the C-type (carbonaceous) asteroid (162173) Ryugu. The mission performed two landing operations to collect samples of surface and subsurface material, the latter exposed by an artificial impact. We present images of the second touchdown site, finding that ejecta from the impact crater was present at the sample location. Surface pebbles at both landing sites show morphological variations ranging from rugged to smooth, similar to Ryugu’s boulders, and shapes from quasi-spherical to flattened. The samples were returned to Earth on 6 December 2020. We describe the morphology of >5 grams of returned pebbles and sand. Their diverse color, shape, and structure are consistent with the observed materials of Ryugu; we conclude that they are a representative sample of the asteroid.

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