Your search keyword '"Folco, L."' showing total 8 results

1. Strewn field, mineralogy, and petrology of Al Haggounia 001: A unique enstatite chondrite.

Author

Leili, M. H., Chennaoui Aoudjehane, H., Devouard, B., Rochette, P., Gattacceca, J., Folco, L., Gemelli, M., and Baziotis, I.

Subjects

MINERALOGY, PETROLOGY, ENSTATITE, CHONDRITES, ELECTRON probe microanalysis, CARBONACEOUS chondrites (Meteorites), MAGNETIC susceptibility

Abstract

In this work, we investigate macroscopic characteristics, magnetic susceptibility, mineralogy, and mineral composition of Al Haggounia 001. The samples were collected during eight field missions in the period between 2015 and 2019. In the strewn field of about 65 km in length, the specimens are found either on the surface or shallowly buried in loose sediments, which rules out the previous suggestions that this meteorite is a fossil meteorite. Macroscopically, the samples exhibit three major lithologies with various colors, porosities, and distributions of oxidized veins. The data obtained using transmitted and reflected light microscopy, scanning electron microscopy, and electron microprobe analysis confirm the macroscopic observations and show a heterogenous distribution of silicates and metal sulfides. Al Haggounia 001 is composed of enstatite, plagioclase, kamacite, taenite, schreibersite, daubreelite, troilite, graphite, sinoite, and silica polymorphs. We identified a new type of chondrules that are flattened and composed of rods of albite and enstatite, as well as elongated nodules of metal and sulfides, in addition to compression fractures in the form of subparallel veinlets. These features presumably reflect the deformation caused by shock. The magnetic susceptibility of Al Haggounia 001 (4.39 ± 0.20) is much lower than that of usual EH (5.48 ± 0.16) and EL (5.46 ± 0.04) chondrites but is in the range of E finds (5.05 ± 0.43). The thermomagnetic and hysteresis measurements are controlled by type, size, distribution of metal‐sulfide nodules, arrangement of oxyhydroxide veins, and weathering. Al Haggounia 001 is an anomalous meteorite with a polymict nature. It records multiple events revealing its unique origin which expends the groups of enstatite chondrites and provides insights into the complex formation and evolution history of their parent body. [ABSTRACT FROM AUTHOR]

Published

2024

2. Early fluid migration and alteration fronts in the CM chondrite Reckling Peak 17085.

Author

Musolino, A., Suttle, M. D., Folco, L., King, A. J., Poggiali, G., Bates, H. C., Brucato, J. R., and Brearley, A.

Subjects

*ICING (Meteorology), *FLUID flow, *FLUID control, *CHONDRULES, *CHONDRITES

Abstract

Reckling Peak (RKP) 17085 is a newly classified Antarctic CM chondrite that preserves a complex alteration history characterized by mild aqueous alteration (CM2.7), overprinted by a short‐lived thermal metamorphic event (heating stage III [<750°C]), and affected by low‐grade terrestrial weathering. This meteorite contains abundant Fe‐rich bands within the fine‐grained matrix, composed of micron‐scale Fe‐oxyhydroxide minerals. They are interpreted as “alteration fronts” arising due to the dissolution and transport of Fe (typically <500 μm) before being abruptly deposited. This alteration texture is relatively rare among hydrated carbonaceous chondrites, with only five reported instances to date (Murchison, Murray, Allan Hills 81002, Miller Range 07687, and Northwest Africa 5958). Evidence from RKP 17085 suggests that early aqueous alteration operated as multiple geochemically isolated microenvironments, which moved outwards from local point sources within the matrix. Low permeability fine‐grained rims on chondrules appear to have acted as barriers to fluid flow, controlling the migration of fluid across the parent body. Furthermore, the higher porosity regions within the altered fine‐grained matrix represent either void space generated by the dehydration of hydrated minerals during post‐hydration metamorphism and/or sites of ice accretion (water‐ice or C‐bearing ices) preserved within a mildly altered primitive matrix. [ABSTRACT FROM AUTHOR]

Published

2024

3. A microchondrule‐bearing micrometeorite and comparison with microchondrules in CM chondrites.

Author

Suttle, M. D., Genge, M. J., Salge, T., Lee, M. R., Folco, L., Góral, T., Russell, S. S., and Lindgren, P.

Subjects

METEORITES, CRYSTAL structure, PHYLLOSILICATES, CHONDRITES, CHONDRULES, ACCRETION (Astrophysics)

Abstract

We report the discovery of a partially altered microchondrule within a fine‐grained micrometeorite. This object is circular, <10 μm in diameter, and has a cryptocrystalline texture, internal zonation, and a thin S‐bearing rim. These features imply a period of post‐accretion parent body aqueous alteration, in which the former glassy igneous texture was subject to hydration and phyllosilicate formation as well as leaching of fluid‐mobile elements. We compare this microchondrule to three microchondrules found in two CM chondrites: Elephant Moraine (EET) 96029 and Murchison. In all instances, their formation appears closely linked to the late stages of chondrule formation, chondrule recycling, and fine‐grained rim accretion. Likewise, they share cryptocrystalline textures and evidence of mild aqueous alteration and thus similar histories. We also investigate the host micrometeorite's petrology, which includes an unusually Cr‐rich mineralogy, containing both Mn‐chromite spinel and low‐Fe‐Cr‐rich (LICE) anhydrous silicates. Because these two refractory phases cannot form together in a single geochemical reservoir under equilibrium condensation, this micrometeorite's accretionary history requires a complex timeline with formation via nonequilibrium batch crystallization or accumulation of materials from large radial distances. In contrast, the bulk composition of this micrometeorite and its internal textures are consistent with a hydrated carbonaceous chondrite source. This micrometeorite is interpreted as a fragment of fine‐grained rim material that once surrounded a larger parent chondrule and was derived from a primitive carbonaceous parent body; either a CM chondrite or Jupiter family comet. [ABSTRACT FROM AUTHOR]

Published

2019

4. 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

5. Oxygen isotope composition of meteoritic ablation debris from the Transantarctic Mountains: Constraining the parent body and implications for the impact scenario.

Author

Van GINNEKEN, M., SUAVET, C., CORDIER, C., FOLCO, L., ROCHETTE, P., SONZOGNI, C., and PERCHIAZZI, N.

Subjects

OXYGEN isotopes, CHONDRITES, ICE cores, MASS spectrometry, FLUORINATION

Abstract

- Microscopic meteoritic ablation spheres recently found on top of the Victoria Land in Transantarctic Mountains, and in the L2 Dome C and DF2691 Dome Fuji ice core layers document a major impact of a 108 kg (or larger) cosmic body in the Antarctic region about 480 kyr ago. Although of broadly chondritic composition, the exact nature of the impactor is unknown, and whether the impactor struck the Antarctic ice sheet or exploded in the atmosphere is a matter of debate. Based on oxygen isotope analyses of ablation spheres from the Transantarctic Mountains by means of IR-laser fluorination coupled with mass spectrometry, we suggest that they represent the debris of an atmospheric airburst of a primitive asteroid of CV, CO, or CK composition, or a comet with composition similar to the short-period comet 81P/Wild 2. [ABSTRACT FROM AUTHOR]

Published

2012

6. 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

7. An impact origin for the foliation of chondrites

Author

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

Subjects

*CHONDRITES, *PROPERTIES of matter, *CRYSTALLOGRAPHY, *ANISOTROPY

Abstract

Abstract: The origin of the foliation of ordinary chondrites is addressed through the study of the anisotropy of magnetic susceptibility (AMS) of these meteorites, based on a database of 295 different meteorites, including 35 achondrites (HED and SNC). AMS is a reliable proxy for preferred orientation in ordinary chondrites. Moreover, the intensity of magnetic anisotropy is constant over a given chondrite. The intensity of L chondrite petrofabric, evaluated by means of AMS measurements, and shock stage, determined independently by microscopic observation of shock features in silicates, appear to be positively correlated. This suggests that the oblate petrofabric in L chondrites is shock-induced. The inverse correlation between porosity and AMS intensity suggests that hypervelocity impacts compacted and lithified an originally loose material, causing the deformation of metallic Fe, Ni grains. LL and H ordinary chondrites cannot be studied as easily as L chondrites: tetrataenite in LL chondrites affects the AMS in an unpredictable way, and shape anisotropy due to the strong susceptibility of H chondrites imposes strong constraints on sample shape. Our limited dataset for carbonaceous chondrites is compatible with a shock-induced foliation model. The very low degrees of AMS in Rumuruti chondrites testify that, surprisingly, the easily deformable Fe-sulfides in these chondrites show almost no deformation, suggesting that sulfidation is a secondary phenomenon that occurred after the major impacts on the Rumuruti parent body. The weak magnetic anisotropy of Martian meteorites implies that no significant macroscopic deformation took place during the severe impacts suffered by these rocks, which is explained by the weak initial porosity and high compressive strength of these igneous products. [Copyright &y& Elsevier]

Published

2005

8. 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