¹J.Eschrig,¹L.Bonal,²M.Mahlke,²B.Carry,¹P.Beck,³J.Gattacceca
Icarus (in Press) Link to Article [https://doi.org/10.1016/j.icarus.2022.115012]
¹Institut de Planétologie et d’Astrophysique de Grenoble, Université Grenoble Alpes, CNRS CNES, 38000 Grenoble, France
²Université Côte d’Azur, Observatoire de la Côte d’Azur, CNRS, Laboratoire Lagrange, France
³CNRS, Aix Marseille Univ, IRD, Coll France, CEREGE, Aix-en-Provence, France
Copyright Elsevier

The search for asteroidal parent bodies of chondrites through various techniques is an ongoing endeavor. A link between ordinary chondrites (OCs) and S-type asteroids has previously been established by the sample return of the Hayabusa space mission. OCs are the class with the most abundant samples in our meteorite collection. We present an in-depth study of the reflectance spectra of 39 equilibrated and 41 unequilibrated ordinary chondrites (EOCs and UOCs). We demonstrate that consistent measuring conditions are vital for the direct comparison of spectral features between chondrites, otherwise hampering any conclusions. We include a comparison with a total of 466 S-type asteroid reflectance spectra from various databases. We analyze (i) if a difference between EOCs and UOCs as well as between H, L and LL can be seen, (ii) if it is possible to identify unequilibrated and equilibrated S-type asteroid surfaces and (iii) if we can further constrain the match between OCs and S-type asteroids all based on reflectance spectra.

As a first step, we checked the classification of the 31 Antarctic UOCs analyzed in the present work, using petrography and magnetic measurements, and evidenced that 74% of them were misclassified. Reflectance spectra were compared between EOCs and UOCs as well as between H, L and LL chondrites using a set of spectral features including band depths and positions, peak reflectance values, spectral slopes and the Ol/(Ol + Px) ratio. UOCs and EOCs reflectance spectra show no clear-cut dichotomy, but a continuum with some EOCs showing stronger absorption bands and peak reflectance values, while others are comparable to UOCs. Moreover, we show by the example of 6 EOCs that their band depths decrease with decreasing grain size. Based on reflectance spectra alone, it is thus highly challenging to objectively identify an unequilibrated from an equilibrated S-type surface. There is no clear distinction of the chemical groups: only LL EOCs of petrographic type >4 can be distinguished from H and L through less deep 2000 nm band depths and 1000 nm band positions at longer wavelengths. No dichotomy of S-type asteroids can be seen based on the Ol/(Ol + Px) ratio. Their average Ol/(Ol + Px) ratio matches EOCs better than UOCs. A principal component analysis (PCA) was performed illustrating that both the unknown degree of space weathering and the unknown regolith grain size on asteroid surfaces hinder the distinction between equilibrated and unequilibrated surfaces. Lastly, an anti-correlation between the diameter of the asteroids and their 1000 nm band depth is found indicating that larger sized S-type asteroids show finer grained surfaces.

¹Bernard Marty
Icarus (in Press) Link to Article [https://doi.org/10.1016/j.icarus.2022.115020]
¹Université de Lorraine, CNRS, CRPG, F-54000 Nancy, France
Copyright Elsevier

The elemental and isotopic compositions of noble gases trapped in primitive meteorites have the potential to yield stringent constraints on the origin of matter in the solar system. The isotopic compositions of key elements like O, Ti, Ru, Mo suggest that the Earth accreted from material having similarities with two classes of meteorites, carbonaceous chondrites (CC) and non‑carbonaceous chondrites (NC), in particular enstatite chondrites (EC). In this contribution, I examine published noble gas (neon and argon) data for CI-CM as representative of CCs, and ECs as representative of NC terrestrial building blocks. Data were corrected for contributions of cosmic ray-produced isotopes in order to identify the trapped component compositions. For both CCs and ECs, corrected noble gas data indicate that high temperature objects such as chondrules were evolving in a dusty environment. The dust consisted of refractory phases including nanodiamonds, impacts-related debris, medium to low temperature phases mainly made of organics and, in the case of CC, hydrated minerals and icy grains. Remnants of such a dust are found as rims around chondrules and as a matrix between high temperature assemblages. The dust was probably the main source of volatiles on Earth.

In terrestrial reservoirs, covariations of 20Ne/22Ne ratios with 36Ar/22Ne ratios are consistent with mixing between a solar-like neon component trapped in the mantle and a chondritic Ne–Ar component mainly present in the atmosphere and hydrosphere. The chondritic end-member is clearly of the CC type and excludes EC-like material as the source of atmospheric volatiles. In addition to CC-like material, the isotopic composition of heavy noble gases (Kr and Xe) in the atmosphere points to a ~ 20% contribution of cometary material akin of the composition of comet 67P/Churyumov-Gerasimenko. In contrast, comets might have contributed less than 1% terrestrial water, C and N. Solar-like neon in the terrestrial mantle might have originated from solar irradiation of free-floating dust before parent body compaction, but this would require a cleared, dust-free environment. Trapping of nebular gas into forming solids during the gas epoch of the nascent solar system appears a more promising possibility. For other mantle volatiles, the stable isotopes of H, N, Ar, Kr and Xe point to a chondritic origin. The hydrogen and nitrogen isotopic signatures of mantle rocks and minerals are consistent with an EC-like contribution whereas those of heavy noble gases are still too imprecise to conclude. Further progress in the field will require high precision analysis of noble gases (in particular, Kr and Xe) trapped in the terrestrial (and martian) mantle(s), as well as documenting the composition of the Venusian atmosphere.