M. Bourot-Denise’s research while affiliated with UPMC and other places
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Polymict chondritic breccias—rocks composed of fragments originating from different chondritic parent bodies—are of particular interest because they give insights into the mixing of asteroids in the main asteroid belt (occurrence, encounter velocity, transfer time). We describe Northwest Africa (NWA) 5764, a brecciated LL6 chondrite that contains a >16 cm3 L4 clast. The L clast was incorporated in the breccia through a nondestructive, low-velocity impact. Identical cosmic-ray exposure ages of the L clast and the LL host (36.6 ± 5.8 Myr), suggest a short transfer time of the L meteoroid to the LL parent body of 0.1 ± 8.1 Myr, if that meteoroid was no larger than a few meters. NWA 5764 (together with St. Mesmin, Dimmitt, and Glanerbrug) shows that effective mixing is possible between ordinary chondrite parent bodies. In NWA 5764 this mixing occurred after the peak of thermal metamorphism on the LL parent body, i.e., at least several tens of Myr after the formation of the solar system. The U,Th-He ages of the L clast and LL host, identical at about 2.9 Ga, might date the final assembly of the breccia, indicating relatively young mixing in the main asteroid belt as previously evidenced in St. Mesmin.
The Paris chondrite provides an excellent opportunity to study CM chondrules and refractory inclusions in a more pristine state than currently possible from other CMs, and to investigate the earliest stages of aqueous alteration captured within a single CM bulk composition. It was found in the effects of a former colonial mining engineer and may have been an observed fall. The texture, mineralogy, petrography, magnetic properties and chemical and isotopic compositions are consistent with classification as a CM2 chondrite. There are ∼45 vol.% high-temperature components mainly Type I chondrules (with olivine mostly Fa0–2, mean Fa0.9) with granular textures because of low mesostasis abundances. Type II chondrules contain olivine Fa7 to Fa76. These are dominantly of Type IIA, but there are IIAB and IIB chondrules, II(A)B chondrules with minor highly ferroan olivine, and IIA(C) with augite as the only pyroxene. The refractory inclusions in Paris are amoeboid olivine aggregates (AOAs) and fine-grained spinel-rich Ca–Al-rich inclusions (CAIs). The CAI phases formed in the sequence hibonite, perovskite, grossite, spinel, gehlenite, anorthite, diopside/fassaite and forsterite. The most refractory phases are embedded in spinel, which also occurs as massive nodules. Refractory metal nuggets are found in many CAI and refractory platinum group element abundances (PGE) decrease following the observed condensation sequences of their host phases. Mn–Cr isotope measurements of mineral separates from Paris define a regression line with a slope of 53Mn/55Mn = (5.76 ± 0.76) × 106. If we interpret Cr isotopic systematics as dating Paris components, particularly the chondrules, the age is 4566.44 ± 0.66 Myr, which is close to the age of CAI and puts new constraints on the early evolution of the solar system. Eleven individual Paris samples define an O isotope mixing line that passes through CM2 and CO3 falls and indicates that Paris is a very fresh sample, with variation explained by local differences in the extent of alteration. The anhydrous precursor to the CM2s was CO3-like, but the two groups differed in that the CMs accreted a higher proportion of water. Paris has little matrix (∼47%, plus 8% fine grained rims) and is less altered than other CM chondrites. Chondrule silicates (except mesostasis), CAI phases, submicron forsterite and amorphous silicate in the matrix are all well preserved in the freshest domains, and there is abundant metal preserved (metal alteration stage 1 of Palmer and Lauretta (2011)). Metal and sulfide compositions and textures correspond to the least heated or equilibrated CM chondrites, Category A of Kimura et al. (2011). The composition of tochilinite–cronstedtite intergrowths gives a PCP index of ∼2.9. Cronstedtite is more abundant in the more altered zones whereas in normal highly altered CM chondrites, with petrologic subtype 2.6–2.0 based on the S/SiO2 and ∑FeO/SiO2 ratios in PCP or tochilinite–cronstedtite intergrowths (Rubin et al., 2007), cronstedtite is destroyed by alteration. The matrix in fresh zones has CI chondritic volatile element abundances, but interactions between matrix and chondrules occurred during alteration, modifying the volatile element abundances in the altered zones. Paris has higher trapped Ne contents, more primitive organic compounds, and more primitive organic material than other CMs. There are gradational contacts between domains of different degree of alteration, on the scale of ∼1 cm, but also highly altered clasts, suggesting mainly a water-limited style of alteration, with no significant metamorphic reheating.
NWA2268 is a polymict eucrite discovered in the Sahara, at southwest Algeria, close to the region of Tindouf. This meteorite weighs 65 g and presents a thin black fusion crust. The rock is fine- to medium-grained breccia and contains mineral fragments of plagioclases, pyroxenes, spinel, olivine and silica. The rock contains some basaltic fragments with sub-ophitic or cumulative textures, constituted by plagioclases and exsolved pigeonite. Pyroxferroite grains are present and locally destabilised in an association of hedenbergite, fayalite and silica. It also presents unequilibrated eucritic clast with heterogeneous pyroxenes and plagioclases compositions. Pyroxenes in the all of the other clasts have equilibrated composition, with exolved pigeonites with augite lamellaes. This polymict eucrite contains also partially devitrified glass that represents impact melts linked to impact event. None recrystallization of this glass confirms a lack of post-brecciation metamorphism. Diogenitic fragments are less abundant than 10 %. The oxygen isotopic composition of NWA2268 is Δ17O (−0.43). This meteorite is interpreted as belonging to the HED group attributed to the 4-Vesta asteroid.
Xenoliths are inclusions of a given meteorite group embedded in host
meteorites of a different group. Xenoliths with dimensions between a few
μm and about 1 mm (microxenoliths) are
“meteorite-trapped” analogues of micrometeorites collected
on the Earth. However, they have the unique features of sampling the
zodiacal cloud (1) at more ancient times than those sampled by
micrometeorites and (2) at larger distances from the Sun (corresponding
to the asteroid Main Belt) than that sampled by micrometeorites (1 AU).
Herein we describe a systematic search for new xenoliths and
microxenoliths in H chondrites, aimed at determining their abundance in
these ordinary chondrites, analyzing their mineralogy, and searching for
possible correlations with host meteorite properties. Sixty-six sections
from 40 meteorites have been analyzed. Twenty-four new xenoliths have
been discovered. About 87% of them are microxenoliths (i.e., <1 mm),
only three are >1 mm in their largest dimension. All the newly
discovered xenoliths and microxenoliths are composed of carbonaceous
chondritic material. Hence, the zodiacal cloud was dominated by
carbonaceous material even in past epochs. All the new xenoliths and
microxenoliths have been found in regolith breccias. Hydrous-phase-rich
xenoliths and microxenoliths in H4 and H5 chondrites attest that their
embedding happened after the end of the thermal metamorphism. All these
data suggest that xenoliths and microxenoliths were embedded when their
host meteorites were part of the parent body regolith. This, combined
with the H chondrite impact age distribution, attests that the embedding
may have happened as early as 3.5 Gyr ago.
The insoluble organic matter (IOM) of an unequilibrated enstatite
chondrite Sahara (SAH) 97096 has been investigated using a battery of
analytical techniques. As the enstatite chondrites are thought to have
formed in a reduced environment at higher temperatures than carbonaceous
chondrites, they constitute an interesting comparative material to test
the heterogeneities of the IOM in the solar system and to constrain the
processes that could affect IOM during solar system evolution. The SAH
97096 IOM is found in situ: as submicrometer grains in the network of
fine-grained matrix occurring mostly around chondrules and as inclusions
in metallic nodules, where the carbonaceous matter appears to be more
graphitized. IOM in these two settings has very similar
δ15N and δ13C; this supports the idea
that graphitized inclusions in metal could be formed by metal catalytic
graphitization of matrix IOM. A detailed comparison between the IOM
extracted from a fresh part and a terrestrially weathered part of SAH
97096 shows the similarity between both IOM samples in spite of the high
degree of mineral alteration in the latter. The isolated IOM exhibits a
heterogeneous polyaromatic macromolecular structure, sometimes highly
graphitized, without any detectable free radicals and
deuterium-heterogeneity and having mean H- and N-isotopic compositions
in the range of values observed for carbonaceous chondrites. It contains
some submicrometer-sized areas highly enriched in 15N
(δ15N up to 1600‰). These observations reinforce
the idea that the IOM found in carbonaceous chondrites is a common
component widespread in the solar system. Most of the features of SAH
97096 IOM could be explained by the thermal modification of this main
component.
Abstract– We describe the geological, morphological, and climatic setting of the San Juan meteorite collection area in the Central Depression of the Atacama Desert (Chile). Our recovery activities yielded 48 meteorites corresponding to a minimum of 36 different falls within a 3.88 km2 area. The recovery density is in the range 9–12 falls km−2 depending on pairing, making it the densest among meteorite collection areas in hot deserts. This high meteorite concentration is linked to the long-standing hyperaridity of the area, the stability of the surface pebbles (> Ma), and very low erosion rates of surface pebbles (approximately 30 cm Ma−1 maximum). The San Juan meteorite population is characterized by old terrestrial ages that range from zero to beyond 40 ka, and limited weathering compared with other dense collection areas in hot desert. Chemical weathering in San Juan is slow and mainly controlled by the initial porosity of meteorites. As in the Antarctic and other hot deserts, there is an overabundance of H chondrites and a shortage of LL chondrites compared with the modern falls population, suggesting a recent (< few ka) change in the composition of the meteorite flux to Earth.
The thermal history of a series of EH3 and EL3 chondrites has been investigated by studying the degree of structural order of the organic matter (OM) located and characterized in matrix areas by Raman micro-spectroscopy. By comparison with unequilibrated ordinary chondrites (UOCs) and CO and CV carbonaceous chondrites, the following petrologic types have been assigned to various E chondrites: Sahara 97096 and Allan Hills 84206: 3.1–3.4; Allan Hills 85170 and Parsa: 3.5; Allan Hills 85119: 3.7; Qingzhen, MacAlpine Hills 88136 and MacAlpine Hills 88184: 3.6–3.7. The petrologic type of Qingzhen is consistent with the abundance of the P3 noble gas component, a sensitive tracer of the grade of thermal metamorphism. The petrologic types are qualitatively consistent with the abundance of fine-grained matrix for the whole series. No significant effects of shock processes on the structure of OM were observed. However such processes certainly compete with thermal metamorphism and the possibility of an effect cannot be fully discarded, in particular in the less metamorphosed objects. The OM precursors accreted by the EH3 and EL3 parent bodies appear to be fairly similar to those of UOCs and CO and CV carbonaceous chondrites. Raman data however show some slight structural differences that could be partly accounted for by shock processes. The metamorphic history of EH3 and EL3 chondrites has often been described as complex, in particular regarding the combined action of shock and thermal metamorphism. Because OM maturity is mostly controlled by the temperature of peak metamorphism, it is possible to distinguish between the contributions of long duration thermal processes and that of shock processes. Comparison of the petrologic types with the closure temperatures previously derived from opaque mineral assemblages has revealed that the thermal history of EH3 and EL3 chondrites is consistent with a simple asteroidal onion shell model. Thermal metamorphism in enstatite chondrites appears to be fairly similar to that which takes place in other chondrite classes. The complex features recorded by mineralogy and petrology and widely reported in the literature appear to be mostly controlled by shock processes.
Citations (60)
... Yet, such a particular compositional mixing would require validation from laboratory experiments. We cite, however, Gattacceca et al. (2017), who show the presence of L clasts mixing into an LL ordinary chondrite inside the breccia meteorite Northwest Africa 5764, thus pointing to the possibility of mixing among varied ordinary chondrite types as a veneer of darkening agents as well. ...
... Such values indicate that the organics in AMMs were not strongly thermally altered, such as the IOM extracted from carbonaceous chondrites (CCs). Meteorites that experimented organic maturation through parent body processes exhibit larger intensity ratio of the D and G bands as well as FWHM-D progressively decreasing toward 100 cm -1 for the most altered chondrites (Bonal, 2006;Bonal et al., 2007). The values measured in AMMs indicate that they did not experiment thermal metamorphism as intense as the one encountered in ordinary chondrites (OCs). ...
... The probable importance of evaporation as a process in the solar nebula has led to numerous evaporation experiments, at 1 atm and at lower pressures, for elements such as alkalis from silicate melts (Tsuchiyama et al., 1981; Mura, 1989; Shimaoka and Nakamura, 1990; Yu and Hewins, 1998; Yu et al., 1998; Tissandier et al., 1998; Wang et al., 1999; Nagahara and Ozawa, 2000b). An important result of these experiments has been the development of a theoretical framework for understanding evaporation and its consequences on isotopic mass fractionation (e.g., Young et al., 1998; Humayun and Cassen, 2000; Nagahara and Ozawa, 2000a; Alexander, 2001) and numerous alkali condensation experiments (Ikeda and Kimura, 1985; Biggar; 1986; Lewis et al.,1993; Georges et al., 2000). ...
... These include the anomalous, but heavily weathered, C chondrite Acfer 094 (3.00), the CO3 chondrites DOM 08006 (3.00), and ALHA 77307 (3.01), and regions of matrix in the LL3.00 chondrite Semarkona (Greshake, 1997;Davidson et al. 2019;Brearley, 1993;Dobrică and Brearley, 2020a). Additionally, there are now a number of meteorites that are considered to be petrologic type 2 chondrites that exhibit minimal evidence of aqueous alteration and also preserve matrices that are comparatively unaltered, such as the CM chondrites Paris (Hewins et al. 2014;Leroux et al. 2015), Asuka 12169, and Asuka 12236 (Kimura et al. 2020;Noguchi et al. 2021), as well as the CR chondrites QUE 99177, MET 00426, and GRV 021710 (Abreu and Brearley, 2010;Davidson et al. 2019). It is, however, important to recognize that almost all CM chondrites are breccias and consist of clasts that have experienced variable degrees of alteration, as documented in Paris (Hewins et al. 2014). ...
... Primitive volatile-rich matter, analogous to CI chondrites, has been found in several meteorites as xenoliths (i.e., clasts), including CR, CH, CB, OC, HED, and ureilites (e.g., Bischoff et al., 1993aBischoff et al., , 1993bEndreß et al., 1994;Zolensky et al., 1996;Briani et al., 2012;Bischoff et al., 2018;Patzek et al., 2018;Goodrich et al., 2019). These volatile-rich clasts bear significant amounts of aqueous alteration-related minerals such as phyllosilicates, carbonates, and magnetite. ...
... Most of the CMs are dominated by aqueous alteration products including phyllosilicates (e.g., serpentines), Fe sulfides (pyrrhotite, pentlandite, tochilinite), magnetite, carbonates (e.g., aragonite, calcite, dolomite), Fe-oxyhydroxides and halides (Brearley et al., 2006). Using petrologic criteria, Rubin et al. (2007) classified CM chondrites as subtypes 2.6-2.0, with the recent characterization of minimally aqueously altered CMs extending the classification scheme to subtypes 2.7-3.0 (Hewins et al., 2014;Kimura et al., 2020;Lentfort et al., 2021;Leroux et al., 2015;Marrocchi et al., 2014;Rubin, 2015). The discovery of minimally altered CMs has also reinforced the debate on the relationship between CM and CO (Ornans-type) chondrites, which sometimes share overlapping O-isotopic compositions (Greenwood et al., 2023;Hewins et al., 2014;Kimura et al., 2020). ...
... Dans cette étude, nous avons identifié l'eucrite AW 200, un nouveau membre de ce groupe du Sahara. antérieures (Seddiki, 2011;Seddiki et al., 2017Seddiki et al., , 2007 ...
... Type 3s are further divided into 3.0-3.9 based on induced thermoluminescence properties (Sears et al., 1980), but also by textures of opaque minerals (Bourot-Denise et al., 1997) and the structure of organics as seen in Raman spectroscopy (Bonal et al., 2006;Bonal et al., 2007). An even finer division of petrographic types <3.2 was defined based on the distribution of Cr 2 O 3 within olivine (Grossman and Brearley, 2005). ...
... The IOM from all other chondrite groups tend to have lower H/C ratios that roughly reflect the intensities of the parent body processing that their host meteorites experienced [10]. However, the extent to which the variations in IOM elemental and isotopic compositions between the most primitive members of each chondrite group were inherited or are the products of parent body processes remains debated [118][119][120]. The bulk IOM in CR chondrites is also, with rare exceptions, the most isotopically anomalous, both in bulk [10] and at micron to submicron scales [118,121,122]. ...
... We also analyzed a particle, with a diameter of 40 µm, extracted from the matrix of the Paris meteorite, a very primitive CM chondrite (Zanda et al. 2010;Hewins et al. 2014). This particle was welded with platinum at the extremity of a tungsten needle using a focused ion beam (see Fig. 1b). ...