Your search keyword '"Folco, L."' showing total 19 results

1. The chondritic impactor origin of the Ni-rich component in Australasian tektites and microtektites.

Author

Folco, L., Rochette, P., D'Orazio, M., and Masotta, M.

Subjects

*MAFIC rocks, *ULTRABASIC rocks, *CASCADE impactors (Meteorological instruments), *CRUST of the earth, *ISOTOPIC analysis

Abstract

In the Earth's crust, Ni is generally concentrated in mafic and ultramafic rocks and is coupled with Mg in Mg-olivine, Mg-pyroxene and spinel. Whether the Ni-rich, and in general, the mafic component of Australasian tektites and microtektites is terrestrial or meteoritic is still debated. To test the origin of the Ni-rich component, we studied the Ni versus Mg distribution in a large geochemical database of Australasian tektites (n = 208) and microtektites (n = 238) from the literature. Nickel contents of up to 428 µg/g in tektites and 678 µg/g in microtektites covary with Mg in tektites and in most (∼85%) of the microtektites defining a mixing trend between crustal and chondritic values, thereby documenting the chondritic origin of the Ni-rich component in Australasian tektites/microtektites. Mixing calculations indicate up to 4% and up to 6% by weight chondritic component in tektites and microtektites, respectively. A possible mafic component of terrestrial origin is observed in a minority of tektite and microtektite specimens. This finding is consistent with previous works suggesting a possible occurrence of a chondritic signature in high-Ni tektites, based on the study of highly siderophile elements and Os isotopes, and high-Ni microtektites, based on Ni, Co, and Cr ratios. The combined geochemical and isotopic analyses of high-Ni tektites and microtektites in collections worldwide may thus reveal the chondritic impactor type that generated one of the presumably largest impacts in the Cenozoic. [ABSTRACT FROM AUTHOR]

Published

2023

2. Microscopic impactor debris at Kamil Crater (Egypt): The origin of the Fe-Ni oxide spherules.

Author

Folco, L., Carone, L., D'Orazio, M., Cordier, C., Suttle, M.D., van Ginneken, M., and Masotta, M.

Subjects

*ELECTRON probe microanalysis, *LIQUID metals, *METALLIC oxides, *CRUST of the earth, *CASCADE impactors (Meteorological instruments), *LUNAR craters, *MAGNETITE

Abstract

Kamil crater (Egypt) is a natural laboratory for the study of processes and products associated with the impacts of small iron projectiles on the Earth's crust. In particular, because of the distinctive composition of the impactor (an ungrouped Ni-rich ataxite) and the target (Cretaceous sandstones and minor wackes) it offers a unique opportunity to study impactor–target physical–chemical interactions. Continuing the study of impact melt ejecta, we investigated the mineralogy and geochemistry of 25 Fe-Ni spherules - representative of a suite of 135 - recovered from the soil around the crater. Samples were collected during our 2010 geophysical expedition and investigated by combining scanning electron microscope imaging, electron probe microanalyzer and Raman spectroscopy analyses. Spherules range in size from 100 to 500 µm and show a variety of dendritic textures and mineral compositions dominated by Fe-Ni oxides of the wüstite – bunsenite and magnetite – trevorite series or Fe-Ni metal. All these features indicate quenching of high temperature (1600–1500 °C) oxide or metal liquid droplets under varying oxidizing conditions. A geochemical affinity with the iron impactor recorded by the Fe, Co, Ni ratios in the constituent phases (average Ni/Co element ratio of 25.1 ± 7.6; average Ni/(Ni + Fe) molar ratio of 0.21 ± 0.13), combined with target contamination (i.e., the ubiquitous occurrence of Si and Al from trace to minor amounts), document their origin as impact melt spherules formed through the physical and chemical interaction between metal projectile and silicate target melts and air. We propose a petrogenetic model that envisions formation as liquid droplet residues of immiscible projectile in a mixed silicate melt and their subsequent separation as individual spherules by stripping during hypervelocity ejection. We also argue that this model applies to all impact events produced by small iron projectiles and that such individual Fe-Ni oxide and metal spherules should be common impact products, despite little documentation in the literature. Our detailed mineralogical and geochemical characterization will facilitate their distinction from other, similar spherules of different origin (cosmic spherules, ablation spherules) often encountered in the geologic record. [ABSTRACT FROM AUTHOR]

Published

2022

3. Study of a set of micrometeorites from Antarctica using magnetic and ESR methods coupled with micro-XRF

Author

Marfaing, J., Rochette, P., Pellerey, J., Chaurand, P., Suavet, C., and Folco, L.

Published

2008

4. Asteroids accretion, differentiation, and break-up in the Vesta source region: Evidence from cosmochemistry of mesosiderites.

Author

Iannini Lelarge, S., Folco, L., Masotta, M., Greenwood, R.C., Russell, S.S., and Bates, H.C.

Subjects

*OXYGEN isotopes, *COSMOCHEMISTRY, *SOLAR system, *ASTEROIDS, *CORE materials, *ISOTOPIC analysis, *ORIGIN of planets

Abstract

The cosmochemistry of meteorites provides unique clues on asteroids accretion, differentiation, collisional break-up and reassembly - processes of critical importance for understanding planet formation in the early solar system. Mesosiderites are a complex group of achondrites whose nearly 50:50 metal-silicate composition is interpreted in the literature as resulting from the mixing of core and crustal materials derived from differentiated asteroids. Because of their complex nature and contrasting geochemical, isotopic, and spectroscopic data, the formation mechanism of mesosiderites is still poorly understood and is open to a large variety of planetary differentiation scenarios and collisional histories. In this study, based on new petrographic and geochemical data of 16 mesosiderites, we investigate in detail the proposal that mesosiderites are related to the howardite-eucrite-diogenite (HED) meteorite group, whose parent body is widely considered to be asteroid 4 Vesta (∼500 km diameter), the target of the recent NASA's Dawn mission. We present the first high precision oxygen isotope analyses on the matrix of a set of mesosiderite samples, coupled with new chemical and petrographic analyses of mesosiderites Um Hadid, Estherville, and Mount Padbury. Concordant Δ17O values between mesosiderites (–0.241 ± 0.015 (2σ)) and howardite-eucrite-diogenites (−0.241 ± 0.017‰ (2σ)) indicate that they derived from the same oxygen isotope reservoir, but petrological evidence, in particular the distinctly lower Fe/Mn ratios and the larger lithological diversity in mesosiderites, indicates that they formed within different parent bodies. This suggests that mesosiderites and howardite-eucrite-diogenites originated in distinct parent bodies that accreted in the 4 Vesta source region but experienced different geologic evolution in terms of crustal differentiation and impact history, which were more complex and catastrophic in the mesosiderite parent body. [ABSTRACT FROM AUTHOR]

Published

2022

5. The aqueous alteration of GEMS-like amorphous silicate in a chondritic micrometeorite by Antarctic water.

Author

Suttle, M.D., Folco, L., Genge, M.J., Franchi, I.A., Campanale, F., Mugnaioli, E., and Zhao, X.

Subjects

*DEUTERIUM, *SILICATES, *EXTREME value theory, *ANTARCTIC ice, *WATER, *LOW temperatures, *CHEMICAL weathering, *CRYSTAL whiskers

Abstract

We analysed the heterogenous fine-grained (sub-μm) matrix of a small (58 × 93 μm), unmelted and minimally heated (<350 °C) micrometeorite (CP94-050-052) recovered from Antarctic blue ice. This particle contains some unaltered highly primitive phases, including refractory anhydrous high-Mg silicates and submicron crystalline needle-shaped acicular grains interpreted as enstatite whiskers. The particle also contains an abundance of micron-sized Fe-rich grains, which span a compositional and textural continuum between amorphous oxygen-rich silicate and poorly crystalline Fe-rich phyllosilicate (cronstedtite). These Fe-rich grains are here interpreted as secondary phases formed by aqueous alteration. Their inferred anhydrous precursors were likely primitive "GEMS-like" amorphous Fe-Mg-silicates. This micrometeorite's bulk chemical composition and mineralogy suggest either a carbonaceous chondrite or cometary origin. However, the particle's average O-isotope composition (δ17O: −12.4‰ [±5.0‰], δ18O: −24.0‰ [±2.3‰] and Δ17O at +0.1‰ [±4.8‰] is distinct from all previously measured chondritic materials. Instead this value is intermediate between primitive chondritic materials and the composition of Antarctic water – strongly implying that the particle was heavily affected by Antarctic alteration. Analysis of the micrometeorite's H-isotopes reveals low deuterium abundances (δD: −217‰ to −173‰ [±43–47‰]) paired with high H abundances (and thus high water contents [<25 wt.%]). Although both water contents and H-isotope compositions overlap with those reported in CM chondrites, the datapoints measured from CP94-050-052 extend to more extreme values. Further supporting the idea that the aqueous alteration that affected this micrometeorite operated under different environmental conditions to asteroidal settings. These data collectively demonstrate partial isotopic exchange with light (δ18O-poor, δD-poor) terrestrial fluids whilst the micrometeorite resided in Antarctica. Although this micrometeorite may have been aqueously altered whilst on its parent body this cannot be conclusively demonstrated due to the extent of the weathering overprint. Antarctic alteration operated at significantly higher water-to-rock ratios than chondritic settings. Despite these differences the extent of secondary replacement and the duration of alteration were limited with mafic silicates remaining unaffected. The combined alteration conditions for this particle likely operated over short timescales (<24 h), under mildly alkaline conditions (∼pH 8) and at low temperatures (<50 °C), this could have occurred during the micrometeorite's extraction from blue ice. [ABSTRACT FROM AUTHOR]

Published

2021

6. Intense aqueous alteration on C-type asteroids: Perspectives from giant fine-grained micrometeorites.

Author

Suttle, M.D., Folco, L., Genge, M.J., Russell, S.S., Najorka, J., and van Ginneken, M.

Subjects

*ASTEROIDS, *METEORITES, *COSMIC dust, *CHONDRITES, *PHYLLOSILICATES

Abstract

Abstract This study explores the petrology of five giant (>400 μm) hydrated fine-grained micrometeorites from the Transantarctic Mountain (TAM) micrometeorite collection. For the first time, the extent and mechanisms of aqueous alteration in unmelted cosmic dust are evaluated and quantified. We use a range of criteria, previously defined for use on hydrated chondrites, including phyllosilicate fraction, matrix geochemistry and micro textures. Collectively, these micrometeorites represent ∼2.22 mm2 of intensely altered hydrated chondritic matrix (with petrologic subtypes of <1.2 in the scheme of Howard et al. (2015)) and reveal a range of alteration styles. Two particles are found to contain pseudomorphic chondrules with thick fine-grained rims, while another micrometeorite contains several aqueously altered CAIs. Their outlines range from well-defined to indistinct, demonstrating that the advanced stages of aqueous alteration progressively remove evidence of coarse-grained components. The remaining two micrometeorites entirely lack coarse-grained components but are similarly altered. Thus, the combined chondrule-to-matrix ratio among these giant micrometeorites is extremely low (6.45 area%), and significantly below the average ratio found in typical CM or CR chondrites (∼20%, Weisberg et al., 2006). Our findings are consistent with previous analyses from smaller Antarctic micrometeorites, which suggest that chondrules (and CAIs) derived from hydrated carbonaceous chondrite parent bodies are underrepresented among the micrometeorite flux, even when considering contributions from coarse-grained micrometeorites. Therefore, to explain the relative paucity of anhydrous material, we propose that the flux of fine-grained micrometeorites is primarily derived from intensely aqueously altered, primitive C-type asteroids, which have lost the majority of their refractory coarse-grained components by replacement with secondary phyllosilicate minerals. [ABSTRACT FROM AUTHOR]

Published

2019

7. Australasian microtektites: Impactor identification using Cr, Co and Ni ratios.

Author

Folco, L., Glass, B.P., D'Orazio, M., and Rochette, P.

Subjects

*METEORITICS, *CRATERING, *TEKTITE, *ASTEROIDS, *GEOCHEMISTRY

Abstract

Impactor identification is one of the challenges of large-scale impact cratering studies due to the dilution of meteoritic material in impactites (typically < 1 wt%). The nature of the impactor that generated the Australasian tektite/microtektite strewn field, i.e., the largest Cenozoic strewn field (∼15% of the Earth's surface), the youngest (∼0.78 Myr old) on Earth, and the only one without an associated impact crater so far, is an outstanding issue. We identify a chondritic impactor signature in 77 Australasian microtektites (size range: ∼200–700 µm) from within 3000 km from the hypothetical impact location in Indochina (∼17°N, 107°E) based on variations of Cr, Co and Ni interelement ratios in a Co/Ni vs Cr/Ni space (46 microtektites analyzed in this work by Laser Ablation-Inductively Coupled Plasma -Mass Spectrometry and 31 from literature by means of Neutron Activation Analyses with Cr, Co and Ni concentrations up to ∼370, 50 and 680 µg/g, respectively). Despite substantial overlap in Cr/Ni versus Co/Ni composition for several meteorite types with chondritic composition (chondrites and primitive achondrites), regression calculation based on ∼85% of the studied microtektites best fit a mixing line between crustal compositions and an LL chondrite. However, due to some scatter mainly in the Cr versus Ni ratios in the considered dataset, an LL chondrite may not be the best fit to the data amongst impactors of primitive compositions. Eight high Ni/Cr and five low Ni/Cr outlier microtektites (∼15% in total) deviate from the above mixing trend, perhaps resulting from incomplete homogenization of heterogeneous impactor and target precursor materials at the microtektite scale, respectively. Together with previous evidence from the ∼35 Myr old Popigai impact spherules and the ∼1 Myr old Ivory Coast microtektites, our finding suggests that at least three of the five known Cenozoic distal impact ejecta were generated by the impacts of large stony asteroids of chondritic composition, and possibly of ordinary chondritic composition. The impactor signature found in Australasian microtektites documents mixing of target and impactor melts upon impact cratering. This requires target-impactor mixing in both the two competing models in literature for the formation of the Australasian tektites/microtektites: the impact cratering and low-altitude airburst plume models. [ABSTRACT FROM AUTHOR]

Published

2018

8. A common volatilization trend in Transantarctic Mountain and Australasian microtektites: Implications for their formation model and parent crater location

Author

Folco, L., Glass, B.P., D'Orazio, M., and Rochette, P.

Published

2010

9. Meteoritic ablation debris from the Transantarctic Mountains: Evidence for a Tunguska-like impact over Antarctica ca. 480 ka ago

Author

van Ginneken, M., Folco, L., Perchiazzi, N., Rochette, P., and Bland, P.A.

Published

2010

10. Meteoritic and bedrock constraints on the glacial history of Frontier Mountain in northern Victoria Land, Antarctica

Author

Welten, K.C., Folco, L., Nishiizumi, K., Caffee, M.W., Grimberg, A., Meier, M.M.M., and Kober, F.

Published

2008

11. Meteorites constrain the age of Antarctic ice at the Frontier Mountain blue ice field (northern Victoria Land)

Author

Folco, L., Welten, K.C., Jull, A.J.T., Nishiizumi, K., and Zeoli, A.

Published

2006

12. Fossil micrometeorites from Monte dei Corvi: Searching for dust from the Veritas asteroid family and the utility of micrometeorites as a palaeoclimate proxy.

Author

Suttle, M.D., Campanale, F., Folco, L., Tavazzani, L., Meier, M.M.M., Miller, C.G., Hughes, G., Genge, M.J., Salge, T., Spratt, J., and Anand, M.

Subjects

*ASTEROIDS, *FOSSILS, *MARINE sediments, *SEDIMENTARY rocks, *OCEAN bottom, *DUST

Abstract

We searched late Miocene sedimentary rocks in an attempt to recover fossil micrometeorites derived from the Veritas asteroid family. This study was motivated by the previous identification of a pronounced 3He peak (4-5x above background) within marine sediments with ages between ∼8.5–6.9 Ma ago (Montanari et al., 2017. GSA Bulletin, 129:1357–1376). We processed 118.9 kg of sediment from the Monte dei Corvi beach section (Italy), the global type-section for the Tortonian epoch (11.6–7.2 Ma). Samples were collected both before and within the 3He peak. Although a small number of iron-rich (I-type) fossil micrometeorites were recovered from each horizon studied (N total = 20), there is no clear difference between the pre- and intra- 3He peak samples. All micrometeorites are compositionally similar, and three out of five horizons yielded similar abundances and particle sizes. Micrometeorites extracted from sediments at the base of the 3He peak were exclusively small (ø <75 µm), while micrometeorites extracted from sediments near the highest 3He values were relatively large (ø <270 µm). The recovered fossil micrometeorites are interpreted as samples of the background dust flux derived from metal-bearing chondritic asteroids. The presence of a 3He signature combined with the absence of fossil micrometeorites or extraterrestrial spinels (Boschi et al., 2019, Spec. Pap. Geol. Soc. Am. 542:383–391) unambiguously related to the Veritas event suggests that the Veritas family is composed of highly friable materials that rarely survive on the sea floor to become preserved in the geological record. Our data supports the existing hypothesis that the Veritas asteroid family is an aqueously altered carbonaceous chondrite parent body, one that contains minimal native metal grains or refractory Cr-spinels. The low yield of fossil micrometeorites at Monte dei Corvi is attributed to loss of particles by dissolution whilst they resided on the sea floor but also due to high sedimentation rates leading to dilution of the extraterrestrial dust flux at this site. As with other fossil micrometeorite collections (e.g. Cretaceous chalk [Suttle and Genge, EPSL, 476:132–142]) the I-type spherules have been altered since deposition. In most particles, both magnetite and wüstite remain intact but have been affected by solid state geochemical exchange, characterised by partial leaching of Ni, Co and Cr and implantation of Mn, Mg, Si and Al. In some particles Mn concentrations reach up to 16.6 wt%. Conversely, in some micrometeorites wüstite has been partially dissolved, or even replaced by calcite or ankerite. Finally, we observe evidence for wüstite recrystallisation, forming a second generation of magnetite. This process is suggested to occur by oxidation during residence on the seafloor and has implications for the use of fossil I-type micrometeorites as a potential proxy for probing Earth's upper atmospheric composition (oxidative capacity) in the geological past. However, solutions to the limitations of post-depositional recrystallisation are suggested. Fossil I-type spherules remain a potential tool for palaeo-climatic studies. [ABSTRACT FROM AUTHOR]

Published

2023

13. An impact origin for the foliation of chondrites

Author

Gattacceca, J., Rochette, P., Denise, M., Consolmagno, G., and Folco, L.

Published

2005

14. Fission track age of Transantarctic Mountain microtektites

Author

Folco, L., Bigazzi, G., D’Orazio, M., and Balestrieri, M.L.

Subjects

*FISSION track dating, *GEOCHEMISTRY, *RADIOACTIVE dating, *TEKTITE, *GEOLOGY, *STRONTIUM isotopes, NIOBIUM isotopes

Abstract

Abstract: We determined the fission track age of Transantarctic Mountain microtektites. The plateau method yielded a formation age of 0.85±0.17Ma. This age overlaps within error with that of the catastrophic impact that produced the Australasian tektite–microtektite strewn field ca. 0.8Ma ago. This provides further evidence that Transantarctic Mountain microtektites belong to the Australasian tektite–microtektite strewn field, as previously suggested on the basis of geochemical evidence, Sr–Nd isotope systematics and poorly resolved radiometric data. [Copyright &y& Elsevier]

Published

2011

15. Transantarctic Mountain microtektites: Geochemical affinity with Australasian microtektites

Author

Folco, L., D’Orazio, M., Tiepolo, M., Tonarini, S., Ottolini, L., Perchiazzi, N., Rochette, P., and Glass, B.P.

Subjects

*TEKTITE, *ANALYTICAL geochemistry, *PETROLOGY, *ELECTRON probe microanalysis, *MAGNESIUM compounds, *HIGH temperature chemistry, *INDUCTIVELY coupled plasma mass spectrometry, *CONTINENTAL crust, *ALKALI metals

Abstract

Abstract: We extended the petrographic and geochemical dataset for the recently discovered Transantarctic Mountain microtektites in order to check our previous claim that they are related to the Australasian strewn field. Based on color and composition, the 465 microtektites so far identified include two groups of transparent glass spheres less than ca. 800μm in diameter: the most abundant pale-yellow, or normal, microtektites, and the rare pale-green, or high-Mg, microtektites. The major element composition of normal microtektites determined through electron microprobe analysis is characterized by high contents of silica (SiO2 =71.5±3.6 (1σ)wt%) and alumina (Al2O3 =15.5±2.2 (1σ)wt%), low total alkali element contents (0.50–1.85wt%), and MgO abundances <6wt%. The high-Mg microtektites have a distinctly higher MgO content >10wt%. Transantarctic Mountain microtektites contain rare silica-rich (up to 93wt% SiO2) glassy inclusions similar to those found in two Australasian microtektites analyzed here for comparison. These inclusions are interpreted as partially digested, lechatelierite-like inclusions typically found in tektites and microtektites. The major and trace element (by laser ablation – inductively coupled plasma – mass spectrometry) abundance pattern of the Transantarctic Mountain microtektites matches the average upper continental crust composition for most elements. Major deviations include a strong to moderate depletion in volatile elements including Pb, Zn, Na, K, Rb, Sr and Cs, as a likely result of severe volatile loss during the high temperature melting and vaporization of crustal target rocks. The normal and high-Mg Transantarctic Mountain microtektites have compositions similar to the most volatile-poor normal and high-Mg Australasian microtektites reported in the literature. Their very low H2O and B contents (by secondary ion mass spectrometry) of 85±58 (1σ) μg/g and 0.53±0.21μg/g, respectively, evidence the extreme volatile loss characteristically observed in tektites. The Sr and Nd isotopic compositions of multigrain samples of Transantarctic Mountain microtektites are 87Sr/86Sr≈0.71629 and 143Nd/144Nd≈0.51209, and fall into the Australasian tektite compositional field. The Nd model age calculated with respect to the chondritic uniform reservoir (CHUR) is TNd CHUR ≈1.1Ga, indicating a Meso-Proterozoic crustal source rock, as was derived for Australasian tektites as well. Coupled with the Quaternary age from the literature, the extended dataset presented in this work strengthens our previous conclusion that Transantarctic Mountain microtektites represent a major southward extension of the Australasian tektite/microtektite strewn field. Furthermore, the significant depletion in volatile elements (i.e., Pb, B, Na, K, Zn, Rb, Sr and Cs) of both normal and high-Mg Transantarctic Mountain microtektites relative to the Australasian ones provide us with further confirmation of a possible relationship between high temperature–time regimes in the microtektite-forming process and ejection distance. [Copyright &y& Elsevier]

Published

2009

16. Fluid-assisted metasomatic processes on planetary bodies: Evidence from vestan lithologies.

Author

Shisseh, T., Chennaoui Aoudjehane, H., Barrat, J.A., Zanda, B., Hewins, R.H., Agee, C.B., Folco, L., Jacquet, E., and Pont, S.

Subjects

*METASOMATISM, *ALUMINUM oxide, *PYROXENE, *FRACTURE mechanics, *OLIVINE, *PLAGIOCLASE, *GOLD ores

Abstract

The mechanisms responsible for the formation of Fe-rich, metasomatic features in eucrites and their debris in howardites are yet controversial. In this study, secondary phases found in polymict eucrite NWA (Northwest Africa) 11911, howardite NWA 1664, monomict eucrite NWA 8675 and unbrecciated basaltic eucrite NWA 13269 were investigated to elucidate their origin and history of formation. Among them, NWA 11911 is the only rock that displays widespread Fe-enrichment near fractures in unequilibrated and slightly equilibrated basaltic clasts and pyroxene fragments. Fayalitic olivine veinlets with various textures, thicknesses and compositions (Fa 64-82) are detected in unequilibrated pyroxenes in NWA 11911, NWA 1664 and NWA 8675. Neighbouring Fe-enriched pyroxene is also Al-depleted compared to magmatic pyroxene (Al 2 O 3 = ∼0.3 wt%). NWA 13269 contains Ca-rich plagioclase (An 97-98) veinlets associated with Cr-spinel, but apparently no Fe-enrichment in pyroxene nor ferroan olivine despite a careful search. Olivine veinlets have been also detected in equilibrated pyroxene in NWA 11911. Our observations support the fluid-assisted metasomatism scenario that involves the circulation of hydrothermal fluids throughout the fractures of eucritic material. [ABSTRACT FROM AUTHOR]

Published

2023

17. Space weathering, reddening and gardening of asteroids: A complex problem

Author

Moretti, P.F., Maras, A., and Folco, L.

Subjects

*CHONDRITES, *ASTEROIDS, *INFRARED spectra, *SPECTRUM analysis

Abstract

Abstract: The association of ordinary chondrites and their parent bodies through their visible and near infrared spectra is still a debate. In fact, many asteroids show reddened spectra, while the ordinary chondrites do not. In the framework of the space weathering of asteroid surfaces, the interpretation of the reddening, darkening, and depletion of band depths is not as simple as previously described. We present a summary of the recent results in the study of the reddening of the spectra. To date, different mechanisms have been proposed to explain some properties of spectra, but a complete scenario capable of reproducing the whole set of observations is still missing. [Copyright &y& Elsevier]

Published

2007

18. Definition and use of functional analogues in planetary exploration.

Author

Foucher, F., Hickman-Lewis, K., Hutzler, A., Joy, K.H., Folco, L., Bridges, J.C., Wozniakiewicz, P., Martínez-Frías, J., Debaille, V., Zolensky, M., Yano, H., Bost, N., Ferrière, L., Lee, M., Michalski, J., Schroeven-Deceuninck, H., Kminek, G., Viso, M., Russell, S., and Smith, C.

Subjects

*PLANETARY exploration, *INSTRUMENT flying, *SPACE exploration, *TRAIN schedules, *FUNCTIONAL beverages, *EXTRATERRESTRIAL life, *DEFINITIONS, *EVALUATION methodology

Abstract

The practical limitations inherent to human and robotic planetary exploration necessitate the development of specific protocols and methods. This non-standard approach requires testing and validation phases in order to optimise instrumental setups and improve data interpretation; this can occur prior to, during, or even after a mission. Flight instruments, and/or their spare models, may be evaluated using relevant terrestrial materials and/or locations. These materials are called analogues: "analogue sites" for large-scale locations, and "analogue samples" for smaller-scale materials. Depending on the scientific domain, the word "analogue" may carry different meanings but is invariably used to denote objects having compositions and/or physical properties similar to specific extraterrestrial objects. However, due to the variability in composition and properties of natural materials, there are always – inevitably – some differences between the analogue and the object(s) to which it refers. In analogue studies, it is, thus, important to focus on the specific properties that need to be imitated and to consider analogue properties rather than analogue sites or samples alone. Here, we introduce the concept of "functional analogues". We first make an overview of the different types of analogues and sort them according to their utility. We then describe how different types of functional analogues can be used throughout the timeline of space missions, from the evaluation of different methods in the definition of a mission to understanding the results acquired by probes exploring extraterrestrial bodies. Finally, logical pathways are outlined that facilitate the selection of the best-suited functional analogue(s) according to their intended use and taking into account practical limitations. • There are inevitably some differences between an analogue and the object(s) to which it refers. • "Functional analogues" are defined according to the specific properties that need to be imitated. • Functional analogues are useful throughout the timeline of space missions (before, during and after). • Logical pathways permit the selection of the best-suited functional analogue(s). [ABSTRACT FROM AUTHOR]

Published

2021

19. Isotopic and textural analysis of giant unmelted micrometeorites – identification of new material from intensely altered 16O-poor water-rich asteroids.

Author

Suttle, M.D., Dionnet, Z., Franchi, I., Folco, L., Gibson, J., Greenwood, R.C., Rotundi, A., King, A., and Russell, S.S.

Subjects

*CARBONACEOUS chondrites (Meteorites), *CHONDRITES, *ISOTOPIC analysis, *ASTEROIDS, *OXYGEN isotopes, *CHONDRULES, *METEORITES

Abstract

• Micro-CT and O-isotopes identify the parent bodies of giant unmelted micrometeorites. • Discovery new hydrated carbonaceous chondrite group linked to water-rich asteroids. • Atmospheric entry removes friable meteorites but these can survive as micrometeorites. • Hydrated CR chondrite fragments common among the giant micrometeorite flux. • Identification of the first micrometeorite derived from an enstatite chondrite. Bulk oxygen isotope data has the potential to match extraterrestrial samples to parent body sources based on distinctive δ 18 O and Δ 17 O ratios. We analysed 10 giant (>500 μm) micrometeorites using combined micro-Computer Tomography (μCT) and O-isotope analysis to pair internal textures to inferred parent body groups. We identify three ordinary chondrite particles (L and LL groups), four from CR chondrites and the first micrometeorite from the enstatite chondrite (EH4) group. In addition, two micrometeorites are from hydrated carbonaceous chondrite parent bodies with 16O-poor isotopic compositions and plot above the terrestrial fractionation line. They experienced intense aqueous alteration, contain pseudomorphic chondrules and are petrographically similar to the CM1/CR1 chondrites. These micrometeorites may be members of the newly established CY chondrites and/or derived from the enigmatic " Group 4 " micrometeorite population, previously identified by Yada et al., 2005 [GCA, 69:5789-5804], Suavet et al., 2010 [EPSL, 293:313-320] (and others). One of our 16O-poor micrometeorite plots on the same isotopic trendline as the CO, CM and CY chondrites – " the CM mixing line " (with a slope of ∼0.7 and a δ 17 O intercept of -4.23‰), this implies a close relationship and potentially a genetic link to these hydrated chondrites. If position along the CM mixing line reflects the amount of 16O-poor (heavy) water-ice accreted onto the parent body at formation, then the CY chondrites and these 16O-poor micrometeorites must have accreted at least as much water-ice as CM chondrites but potentially more. In addition, thermal metamorphism could have played a role in further raising the bulk O-isotope compositions through the preferential loss of isotopically light water during phyllosilicate dehydration. The study of micrometeorites provides insights into asteroid belt diversity through the discovery of material not currently sampled by larger meteorites, perhaps as a result of atmospheric entry biases preventing the survival of large blocks of friable hydrated material. [ABSTRACT FROM AUTHOR]

Published

2020