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2. Solar wind contributions to Earth’s oceans

Author

Hope A. Ishii, Catherine A. Dukes, Anthony M. Monterrosa, Michelle S. Thompson, Lindsay P. Keller, John P. Bradley, Phillip A. Bland, Lucy V. Forman, Khalid Hattar, Nicholas E. Timms, Lydia J. Hallis, Denis Fougerouse, Luke Daly, Fred Jourdan, Mark J. Loeffler, Zakaria Quadir, Martin Lee, Roy Christoffersen, Tobias Salge, William D.A. Rickard, M. A. Cox, Steven M. Reddy, David W. Saxey, J. Aguiar, and Evangelos Christou

Subjects
Solar System, Olivine, Astronomy and Astrophysics, engineering.material, Regolith, Silicate, Astrobiology, chemistry.chemical_compound, Solar wind, chemistry, Asteroid, Extraterrestrial life, engineering, Environmental science, Earth (classical element)
Abstract

The isotopic composition of water in Earth’s oceans is challenging to recreate using a plausible mixture of known extraterrestrial sources such as asteroids—an additional isotopically light reservoir is required. The Sun’s solar wind could provide an answer to balance Earth’s water budget. We used atom probe tomography to directly observe an average ~1 mol% enrichment in water and hydroxyls in the solar-wind-irradiated rim of an olivine grain from the S-type asteroid Itokawa. We also experimentally confirm that H+ irradiation of silicate mineral surfaces produces water molecules. These results suggest that the Itokawa regolith could contain ~20 l m−3 of solar-wind-derived water and that such water reservoirs are probably ubiquitous on airless worlds throughout our Galaxy. The production of this isotopically light water reservoir by solar wind implantation into fine-grained silicates may have been a particularly important process in the early Solar System, potentially providing a means to recreate Earth’s current water isotope ratios. Water and hydroxyl enrichment in the solar-wind-irradiated rim of an olivine grain from asteroid Itokawa suggests that its regolith could contain ~20 l m−3 of water from solar wind—a potential water source for airless planetary bodies.

Published
2021
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4. Mineralogy, petrology, geochemistry, and chronology of the Murrili (H5) meteorite fall: The third recovered fall from the Desert Fireball Network

Author

K. Merigot, Philip A. Bland, Matthias M. M. Meier, Belinda Godel, Gretchen Benedix, Fred Jourdan, Marc W. Caffee, S. Wiggins, Ian A. Franchi, Trent Jansen-Sturgeon, Henner Busemann, Luke Daly, Trudi Kennedy, A. W. R. Bevan, J. M. Cadogan, Richard C. Greenwood, Martin C. Towner, Hadrien A. R. Devillepoix, Eleanor K. Sansom, Jon M. Friedrich, L. Esteban, Robert J. Macke, Robert M. Howie, Colin Maden, D. Stuart, D. Strangway, Seamus Anderson, Lucy V. Forman, Daniel T. Britt, Jonathan Paxman, Celia Mayers, Martin Cupak, and Kees C. Welten

Subjects
Radionuclide, Meteoroid, Geochemistry, Mineralogy, Cosmic ray, 010502 geochemistry & geophysics, 01 natural sciences, Texture (geology), Isotopes of oxygen, Geophysics, Meteorite, 13. Climate action, Space and Planetary Science, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Chronology, Ordinary chondrite
Abstract

Murrili, the third meteorite recovered by the Desert Fireball Network, is analyzed using mineralogy, oxygen isotopes, bulk chemistry, physical properties, noble gases, and cosmogenic radionuclides. The modal mineralogy, bulk chemistry, magnetic susceptibility, physical properties, and oxygen isotopes of Murrili point to it being an H5 ordinary chondrite. It is heterogeneously shocked (S2–S5), depending on the method used to determine it, although Murrili is not obviously brecciated in texture. Cosmogenic radionuclides yield a cosmic ray exposure age of 6–8 Ma, and a pre‐atmospheric meteoroid size of 15–20 cm in radius. Murrili’s fall and subsequent month‐long embedment into the salt lake Kati Thanda significantly altered the whole rock, evident in its Mossbauer spectra, and visual inspection of cut sections. Murrili may have experienced minor, but subsequent, impacts after its formation 4475.3 ± 2.3 Ma, which left it heterogeneously shocked.

Published
2021
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7. A morphologic and crystallographic comparison of CV chondrite matrices

Author

Patrick Trimby, Lucy V. Forman, Nicholas E. Timms, Luke Daly, Gretchen Benedix, and Philip A. Bland

Subjects
education.field_of_study, Materials science, Population, Chondrule, 010502 geochemistry & geophysics, 01 natural sciences, Parent body, Grain size, Crystallography, Geophysics, Allende meteorite, Meteorite, Space and Planetary Science, Chondrite, 0103 physical sciences, education, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Electron backscatter diffraction
Abstract

Meteoritic matrices are commonly classified by their modal mineralogy, alteration, and shock levels. Other “textural” characteristics are not generally considered in classification schemes, yet could carry important information about their genesis and evolution. Terrestrial rocks are routinely described by grain morphology, which has led to morphology‐driven classifications, and identification of controlling processes. This paper investigates three CV chondrites—Allende (CV3.2oxA), Kaba (CV3.0oxB), and Vigarano (CV3.3red)—to determine the morphologic signature of olivine matrix grains. 2D grain size and shape, and crystallographic preferred orientations (CPOs) are quantified via electron backscatter diffraction mapping. Allende contains the largest and most elongate olivine grains, while Vigarano contains the least elongate, and Kaba contains the smallest grains. Weak but notable CPOs exist in some regions proximal to chondrules and one region distal to chondrules, and CPO geometries reveal a weak flattening of the matrix grains against the edge of chondrules within Allende. Kaba contains the least plastically deformed grains, and Allende contains the most plastically deformed grains. We tentatively infer that morphology is controlled by the characteristics of the available population of accreting grains, and aqueous and thermal alteration of the parent body. The extent of overall finite deformation is likely dictated by the location of the sample with respect to compression, the localized environment of the matrix with respect to surrounding material, and the post deformation temperature to induce grain annealing. Our systematic, quantitative process for characterizing meteorite matrices has the potential to provide a framework for comparison within and across meteorite classes, to help resolve how parent body processing differed across and between chondritic asteroids.

Published
2019
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8. Developing atom probe tomography of phyllosilicates in preparation for extra-terrestrial sample return

Author

Martin Lee, William Smith, Ingrid Mccarrol, Lucy V. Forman, Julie M. Cairney, Limei Yang, Luke Daly, William D.A. Rickard, Paul A. J. Bagot, Phillip A. Bland, James Darling, Denis Fougerouse, Steven M. Reddy, David W. Saxey, and Gretchen Benedix

Subjects
Peridotite, Materials science, Olivine, Nanostructure, Mineralogy, Geology, Atom probe, Mars Exploration Program, engineering.material, Exploration of Mars, law.invention, Geochemistry and Petrology, law, Asteroid, engineering, Earth (classical element)
Abstract

Hydrous phyllosilicate minerals, including the serpentine subgroup, are likely to be major constituents of material that will be bought back to Earth by missions to Mars and to primitive asteroids Ryugu and Bennu. Small quantities (< 60 g) of micrometre sized, internally heterogeneous material will be available for study, requiring minimally destructive techniques. Many conventional methods are unsuitable for phyllosilicates as they are typically finely crystalline and electron beam sensitive resulting in amorphisation and dehydration. New tools will be required for nanoscale characterisation of these precious extra‐terrestrial samples. Here we test the effectiveness of atom probe tomography (APT) for this purpose. Using lizardite from the Ronda peridotite, Spain, as a terrestrial analogue, we outline an effective analytical protocol to extract nanoscale chemical and structural measurements of phyllosilicates. The potential of APT is demonstrated by the unexpected finding that the Ronda lizardite contains SiO‐rich nanophases, consistent with opaline silica that formed as a by‐product of the serpentinisation of olivine. Our new APT approach unlocks previously unobservable nanominerals and nanostructures within phyllosilicates owing to resolution limitations of more established imaging techniques. APT will provide unique insights into the processes and products of water/rock interaction on Earth, Mars and primitive asteroids.

Published
2021

9. Defining the Potential of Nanoscale Re‐Os Isotope Systematics Using Atom Probe Microscopy

Author

Luke Daly, Daniel Schwander, Bruce F. Schaefer, Denis Fougerouse, Alexandre La Fontaine, Julie M. Cairney, Phil A. Bland, Steven M. Reddy, David W. Saxey, Simon P. Ringer, Lucy V. Forman, Svetlana G. Tessalina, and William D.A. Rickard

Subjects
Materials science, Isotope, Hydride, Analytical chemistry, Thermal ionization, Geology, 02 engineering and technology, Atom probe, 010502 geochemistry & geophysics, 021001 nanoscience & nanotechnology, Mass spectrometry, 01 natural sciences, Silicate, law.invention, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, law, Isobaric process, 0210 nano-technology, Nanoscopic scale, 0105 earth and related environmental sciences
Abstract

Atom probe microscopy (APM) is a relatively new in situ tool for measuring isotope fractions from nanoscale volumes (< 0.01 μm3). We calculate the theoretical detectable difference of an isotope ratio measurement result from APM using counting statistics of a hypothetical dataset to be ± 4δ or 0.4% (2s). However, challenges associated with APM measurements (e.g., peak ranging, hydride formation and isobaric interferences), result in larger uncertainties if not properly accounted for. We evaluate these factors for Re‐Os isotope ratio measurements by comparing APM and negative thermal ionisation mass spectrometry (N‐TIMS) measurement results of pure Os, pure Re, and two synthetic Re‐Os‐bearing alloys from Schwander et al. (2015) (the original metal alloy (HSE) and alloys produced by heating HSE within silicate liquid (SYN)). From this, we propose a current best practice for APM Re‐Os isotope ratio measurements. Using this refined approach, mean APM and N‐TIMS 187Os/189Os measurement results agree within 0.05% and 2s (pure Os), 0.6–2% and 2s (SYN) and 5–10% (HSE). The good agreement of N‐TIMS and APM 187Os/189Os measurements confirm that APM can extract robust isotope ratios. Therefore, this approach permits nanoscale isotope measurements of Os‐bearing alloys using the Re‐Os geochronometer that could not be measured by conventional measurement principles.

Published
2018
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10. In situ analysis of Refractory Metal Nuggets in carbonaceous chondrites

Author

Chris Ryan, Hongwei Liu, Lucy V. Forman, Martin Saunders, Katy Evans, Luke Daly, Phil A. Bland, S. Moody, Simon P. Ringer, Patrick Trimby, Limei Yang, and K. A. Dyl

Subjects
education.field_of_study, Chemistry, Population, Chondrule, Platinum group, 010502 geochemistry & geophysics, 01 natural sciences, Parent body, Astrobiology, Allende meteorite, Meteorite, Geochemistry and Petrology, Chondrite, 0103 physical sciences, CI chondrite, education, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

Micrometre to sub-micrometre-scale alloys of platinum group elements (PGEs) known as Refractory Metal Nuggets (RMNs) have been observed in primitive meteorites. The Australian Synchrotron X-ray Fluorescence (XRF) beamline, in tandem with the Maia detector, allows rapid detection of PGEs in concentrations as low as 50–100 ppm at 2 μm resolution. Corroborating these analyses with traditional electron microscopy techniques, RMNs can be rapidly identified in situ within carbonaceous chondrites. These results dispute the assumption of most previous studies: that RMNs are unique to Ca–Al-rich inclusions (CAIs). We find that RMNs are, in fact, observed within all components of carbonaceous chondrites, such as the matrix, chondrules (consistent with observations from Schwander et al. (2015b) and Wang et al. (2007)), and sulphides; though the majority of RMNs are still found in CAIs. The chemistry of RMNs reveals a complex diversity of compositions, which nevertheless averages to CI chondrite abundance ratios. This implies that RMNs are the dominant, if not sole host phase for PGEs. One hundred and thirteen RMNs from this study are combined with reported compositions in the literature, and compared to condensation model compositions similar to Berg et al. (2009), RMNs derived experimentally by precipitation (Schwander et al., 2015a), host phase and host meteorite. Comparisons reveal only weak correlations between parent body processes (sulphidation) and nebular processes (condensation and precipitation) with RMN compositions. It appears that none of these processes acting in isolation or in tandem can explain the diversity observed in the RMN population. Our interpretation is that the Solar Nebula inherited an initially compositionally diverse population of RMNs from the Giant Molecular Cloud; that a variety of Solar System processes have acted on that population; but none have completely homogenised it. Most RMNs have experienced disk and asteroidal processing, but some may have retained a primordial composition. RMNs have been identified in pre-solar graphite grains (Croat et al., 2013). We anticipate that pre-solar RMNs will be present elsewhere in primitive meteorites.

Published
2017
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11. Nebula sulfidation and evidence for migration of 'free-floating' refractory metal nuggets revealed by atom probe microscopy

Author

Steven M. Reddy, David W. Saxey, Denis Fougerouse, Phil A. Bland, Luke Daly, William D.A. Rickard, and Lucy V. Forman

Subjects
Refractory metals, Geology, Atom probe, 010502 geochemistry & geophysics, Protoplanetary disk, 01 natural sciences, Astrobiology, law.invention, Petrography, Meteorite, law, 0103 physical sciences, Atomic ratio, Inclusion (mineral), 010303 astronomy & astrophysics, Refractory (planetary science), 0105 earth and related environmental sciences
Abstract

Disk models have been proposed that imply particles migrate rapidly in a protoplanetary disk. However, the only physical constraints on these processes from meteorites are observations of refractory inclusions in cometary material from the NASA Stardust mission. Atom probe microscopy (APM) of sub-micrometer refractory metal nuggets (RMNs) contained within a Sc-Zr–rich ultrarefractory inclusion (URI) from the ALH 77307 carbonaceous Ornans (CO) 3.0 meteorite revealed the presence of sulfur at 0.06–1.00 atomic percent (at%) abundances within RMNs. The mineralogical assemblage, petrographic texture, and flat chondrite-normalized highly siderophile element ratios indicate S exposure was unlikely to have occurred after the RMNs were incorporated into the URI. APM analyses suggest these RMNs were likely “free floating” when they were exposed to a S-condensing gas. This requires early, rapid migration of RMNs to cooler regions of the disk to incorporate S and then cycling back to the Ca-Al–rich inclusion (CAI)–forming region for incorporation in the URI, or conditions in the CAI-forming region that promote the incorporation of S into RMNs.

Published
2017
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12. Murrili meteorite's fall and recovery from Kati Thanda

Author

M. A. Cox, Martin Cupak, Philip A. Bland, Hadrien A. R. Devillepoix, Jonathan Paxman, Trent Jansen-Sturgeon, Lucy V. Forman, Martin C. Towner, Eleanor K. Sansom, Gretchen Benedix, Benjamin A. D. Hartig, and Robert M. Howie

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), Solar System, Meteoroid, FOS: Physical sciences, Context (language use), 010502 geochemistry & geophysics, Geodesy, 01 natural sciences, Fall line, Automated data, Atmosphere, Geophysics, Meteorite, Space and Planetary Science, 0103 physical sciences, 010303 astronomy & astrophysics, Geology, Astrophysics - Earth and Planetary Astrophysics, 0105 earth and related environmental sciences
Abstract

On the 27th of November 2015, at 10:43:45.526 UTC, a fireball was observed across South Australia by ten Desert Fireball Network observatories lasting 6.1 s. A $\sim37$ kg meteoroid entered the atmosphere with a speed of 13.68$\pm0.09\,\mbox{km s}^{-1}$ and was observed ablating from a height of 85 km down to 18 km, having slowed to 3.28$\pm0.21 \,\mbox{km s}^{-1}$. Despite the relatively steep 68.5$^\circ$ trajectory, strong atmospheric winds significantly influenced the darkfight phase and the predicted fall line, but the analysis put the fall site in the centre of Kati Thanda - Lake Eyre South. Kati Thanda has metres-deep mud under its salt-encrusted surface. Reconnaissance of the area where the meteorite landed from a low flying aircraft revealed a 60 cm circular feature in the muddy lake, less than 50 m from the predicted fall line. After a short search, which again employed light aircraft, the meteorite was recovered on the 31st December 2015 from a depth of 42 cm. Murrili is the first recovered observed fall by the digital Desert Fireball Network (DFN). In addition to its scientific value, connecting composition to solar system context via orbital data, the recover demonstrates and validates the capabilities of the DFN, with its next generation remote observatories and automated data reduction pipeline.

Published
2020
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13. Boom boom pow: shock-facilitated aqueous alteration and evidence for two shock events in the Martian nakhlite meteorites

Author

Lucy V. Forman, Samantha Griffin, Patrick Trimby, Lydia J. Hallis, Fabrizio Campanale, Mohsen Bazargan, Martin Lee, Annemarie E. Pickersgill, Sandra Piazolo, Raphael J. Baumgartner, Luke Daly, Gretchen Benedix, Benjamin E. Cohen, Peter Chung, Daly, L, Lee, M, Piazolo, S, Griffin, S, Bazargan, M, Campanale, F, Chung, P, Cohen, B, Pickersgill, A, Hallis, L, Trimby, P, Baumgartner, R, Forman, L, and Benedix, G

Subjects
010504 meteorology & atmospheric sciences, Geochemistry, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Impact crater, Nakhlite, martian meteorites, aqueous alteration, shock metamorphism, Research Articles, 0105 earth and related environmental sciences, Martian, Multidisciplinary, Geofysik, SciAdv r-articles, Geology, Mars Exploration Program, Igneous rock, Geophysics, Augite, Meteorite, 13. Climate action, engineering, Geologi, Planetary Science, Research Article, Electron backscatter diffraction
Abstract

Evidence for impact-generated water on Mars ~633 Ma ago predicts two craters at the nakhlite meteorite’s ejection site., Nakhlite meteorites are ~1.4 to 1.3 Ga old igneous rocks, aqueously altered on Mars ~630 Ma ago. We test the theory that water-rock interaction was impact driven. Electron backscatter diffraction demonstrates that the meteorites Miller Range 03346 and Lafayette were heterogeneously deformed, leading to localized regions of brecciation, plastic deformation, and mechanical twinning of augite. Numerical modeling shows that the pattern of deformation is consistent with shock-generated compressive and tensile stresses. Mesostasis within shocked areas was aqueously altered to phyllosilicates, carbonates, and oxides, suggesting a genetic link between the two processes. We propose that an impact ~630 Ma ago simultaneously deformed the nakhlite parent rocks and generated liquid water by melting of permafrost. Ensuing water-rock interaction focused on shocked mesostasis with a high density of reactive sites. The nakhlite source location must have two spatially correlated craters, one ~630 Ma old and another, ejecting the meteorites, ~11 Ma ago.

Published
2019
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14. Hidden secrets of deformation: Impact-induced compaction within a CV chondrite

Author

Fred J. Ciesla, Gretchen Benedix, Luke Daly, Limei Yang, Patrick Trimby, Lucy V. Forman, Nicholas E. Timms, Gareth S. Collins, Phil A. Bland, Thomas M. Davison, Simon P. Ringer, and Science and Technology Facilities Council (STFC)

Subjects
Geochemistry & Geophysics, 04 Earth Sciences, Mineralogy, Deformation (meteorology), 010502 geochemistry & geophysics, 01 natural sciences, Parent body, Matrix (geology), Allende meteorite, Geochemistry and Petrology, Chondrite, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), compaction, crystallography, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, 02 Physical Sciences, deformation, Chondrule, meteorite, Geophysics, Meteorite, Space and Planetary Science, Allende, impact, Geology, Electron backscatter diffraction
Abstract

The CV3 Allende is one of the most extensively studied meteorites in worldwide collections. It is currently classified as S1—essentially unshocked—using the classification scheme of Stöffler et al. (1991), however recent modelling suggests the low porosity observed in Allende indicates the body should have undergone compaction-related deformation. In this study, we detail previously undetected evidence of impact through use of Electron Backscatter Diffraction mapping to identify deformation microstructures in chondrules, AOAs and matrix grains. Our results demonstrate that forsterite-rich chondrules commonly preserve crystal-plastic microstructures (particularly at their margins); that low-angle boundaries in deformed matrix grains of olivine have a preferred orientation; and that disparities in deformation occur between chondrules, surrounding and non-adjacent matrix grains. We find heterogeneous compaction effects present throughout the matrix, consistent with a highly porous initial material. Given the spatial distribution of these crystal-plastic deformation microstructures, we suggest that this is evidence that Allende has undergone impact-induced compaction from an initially heterogeneous and porous parent body. We suggest that current shock classifications (Stöffler et al., 1991) relying upon data from chondrule interiors do not constrain the complete shock history of a sample.

Published
2016
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15. Understanding the emplacement of Martian volcanic rocks using petrofabrics of the nakhlite meteorites

Author

Martin Lee, Raphael J. Baumgartner, Luke Daly, S. Griffin, Lucy V. Forman, Sandra Piazolo, Gretchen Benedix, Lydia J. Hallis, Peter Chung, Patrick Trimby, Benjamin E. Cohen, Fabrizio Campanale, Daly, L, Piazolo, S, Lee, M, Griffin, S, Chung, P, Campanale, F, Cohen, B, Hallis, L, Trimby, P, Baumgartner, R, Forman, L, and Benedix, G

Subjects
010504 meteorology & atmospheric sciences, Lava, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, Nakhlite, Earth and Planetary Sciences (miscellaneous), electron backscatter diffraction, Petrology, 0105 earth and related environmental sciences, Basalt, geography, geography.geographical_feature_category, Volcanic rock, Igneous rock, Mar, Geophysics, Augite, Meteorite, Space and Planetary Science, petrofabric, nakhlite, engineering, Phenocryst, magmatic petrogenesi, Martian meteorite, Geology
Abstract

In order to validate calculated ages of the Martian crust we require precise radiometric dates from igneous rocks where their provenance on the Martian surface is known. Martian meteorites have been dated precisely and quantitatively, but the launch sites are currently unknown. Inferring the formation environment of a correlated suite of Martian meteorites can constrain the nature and complexity of the volcanic system they formed from. The nakhlite meteorites are such a suite of augite-rich rocks that sample the basaltic crust of Mars, and as such can provide unique insights into its volcanic processes. Using electron backscatter diffraction we have determined the shape-preferred and crystallographic-preferred orientation petrofabrics of four nakhlites (Governador Valadares, Lafayette, Miller Range 03346 and Nakhla) in order to understand the conditions under which their parent rocks formed. In all samples, there is a clear link between the shape-preferred orientation (SPO) and crystallographic-preferred orientation (CPO) of augite phenocrysts. This relationship reveals the three-dimensional shape of the augite crystals using CPO as a proxy for 3D SPO, and also enables a quantitative 3-dimensional petrofabric analysis. All four nakhlites exhibit a foliation defined by the CPO of the augite axis in a plane, although individual meteorites show subtle textural variations. Nakhla and Governador Valadares display a weak CPO lineation within their axis foliation that is interpreted to have developed in a combined pure shear/simple shear flow regime, indicative of emplacement of their parent rock as a subaerial hyperbolic lava flow. By contrast, the foliation dominated CPO petrofabrics of Lafayette and Miller Range 03346 suggest formation in a pure shear dominated regime with little influence of hyperbolic flow. These CPO petrofabrics are indicative of crystal settling in the stagnant portion of cooling magma bodies, or the flattening area of spreading lava flows. The CPO foliation of Lafayette's is substantially weaker than Miller Range 03346, probably due to its higher phenocryst density causing grain-grain interactions that hindered fabric development. The CPO petrofabrics identified can also be used to determine the approximate plane of the Martian surface and the line of magma flow to within ∼20°. Our results suggest that the nakhlite launch crater sampled a complex volcanic edifice that was supplied by at least three distinct magmatic systems limiting the possible locations these rocks could have originated from on Mars.

Published
2019

16. Crystallography of refractory metal nuggets in carbonaceous chondrites: a transmission Kikuchi diffraction approach

Author

Sandra Piazolo, K. A. Dyl, S. Moody, Hongwei Liu, Steven M. Reddy, Simon P. Ringer, Limei Yang, David W. Saxey, Patrick Trimby, Luke Daly, Martin Saunders, Lucy V. Forman, William D.A. Rickard, Denis Fougerouse, and Phil A. Bland

Subjects
Diffraction, 010504 meteorology & atmospheric sciences, Scanning electron microscope, Nucleation, 010502 geochemistry & geophysics, 01 natural sciences, law.invention, Crystallography, Geochemistry and Petrology, law, Transmission electron microscopy, Chondrite, Carbonaceous chondrite, Crystallization, Geology, 0105 earth and related environmental sciences, Electron backscatter diffraction
Abstract

Transmission Kikuchi diffraction (TKD) is a relatively new technique that is currently being developed for geological sample analysis. This technique utilises the transmission capabilities of a scanning electron microscope (SEM) to rapidly and accurately map the crystallographic and geochemical features of an electron transparent sample. TKD uses a similar methodology to traditional electron backscatter diffraction (EBSD), but is capable of achieving a much higher spatial resolution (5–10 nm) (Trimby, 2012; Trimby et al., 2014). Here we apply TKD to refractory metal nuggets (RMNs) which are micrometre to sub-micrometre metal alloys composed of highly siderophile elements (HSEs) found in primitive carbonaceous chondrite meteorites. TKD allows us to analyse RMNs in situ, enabling the characterisation of nanometre-scale variations in chemistry and crystallography, whilst preserving their spatial and crystallographic context. This provides a complete representation of each RMN, permitting detailed interpretation of their formation history.\ud \ud We present TKD analysis of five transmission electron microscopy (TEM) lamellae containing RMNs coupled with EBSD and TEM analyses. These analyses revealed textures and relationships not previously observed in RMNs. These textures indicate some RMNs experienced annealing, forming twins. Some RMNs also acted as nucleation centres, and formed immiscible metal-silicate fluids. In fact, each RMN analysed in this study had different crystallographic textures. These RMNs also had heterogeneous compositions, even between RMNs contained within the same inclusion, host phase and even separated by only a few nanometres. Some RMNs are also affected by secondary processes at low temperature causing exsolution of molybdenite. However, most RMNs had crystallographic textures indicating that the RMN formed prior to their host inclusion. TKD analyses reveal most RMNs have been affected by processing in the protoplanetary disk. Despite this alteration, RMNs still preserve primary crystallographic textures and heterogeneous chemical signatures. This heterogeneity in crystallographic relationships, which mostly suggest that RMNs pre-date their host, is consistent with the idea that there is not a dominant RMN forming process. Each RMN has experienced a complex history, supporting the suggestion of Daly et al. (this issue), that RMNs may preserve a diverse pre-solar chemical signature inherited from the Giant Molecular Cloud.

Published
2017

17. Defining the mechanism for compaction of the CV chondrite parent body

Author

Patrick Trimby, Luke Daly, Lucy V. Forman, Gretchen Benedix, Thomas M. Davison, Nicholas E. Timms, Phil A. Bland, Gareth S. Collins, and Science and Technology Facilities Council (STFC)

Subjects
Geochemistry & Geophysics, Misorientation, 04 Earth Sciences, Compaction, Mineralogy, SOLAR-SYSTEM SOLIDS, 010502 geochemistry & geophysics, 01 natural sciences, Parent body, IMPACT-INDUCED COMPACTION, THERMOMETRY, Allende meteorite, DEFORMATION, Chondrite, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Science & Technology, METEORITE, POROSITY, Chondrule, THERMAL EVOLUTION, Geology, Carbonaceous chondrite, Physical Sciences, OLIVINE, PLANETESIMALS, MATRIX, Electron backscatter diffraction
Abstract

The Allende meteorite, a relatively unaltered member of the CV carbonaceous chondrite group, contains primitive crystallographic textures that can inform our understanding of early Solar System planetary compaction. To test between models of porosity reduction on the CV parent body, complex microstructures within ~0.5-mm-diameter chondrules and ~10-μm-long matrix olivine grains were analyzed by electron backscatter diffraction (EBSD) techniques. The large area map presented is one of the most extensive EBSD maps to have been collected in application to extraterrestrial materials. Chondrule margins preferentially exhibit limited intragrain crystallographic misorientation due to localized crystal-plastic deformation. Crystallographic preferred orientations (CPOs) preserved by matrix olivine grains are strongly coupled to grain shape, most pronounced in shortest dimension , yet are locally variable in orientation and strength. Lithostatic pressure within plausible chondritic model asteroids is not sufficient to drive compaction or create the observed microstructures if the aggregate was cold. Significant local variability in the orientation and intensity of compaction is also inconsistent with a global process. Detailed microstructures indicative of crystal-plastic deformation are consistent with brief heating events that were small in magnitude. When combined with a lack of sintered grains and the spatially heterogeneous CPO, ubiquitous hot isostatic pressing is unlikely to be responsible. Furthermore, Allende is the most metamorphosed CV chondrite, so if sintering occurred at all on the CV parent body it would be evident here. We conclude that the crystallographic textures observed reflect impact compaction and indicate shock-wave directionality. We therefore present some of the first significant evidence for shock compaction of the CV parent body.

Published
2017

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