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Rapid Condensation of the First Solar System Solids Yves Marrocchi, Johan Villeneuve, Emmanuel Jacquet, Maxime Piralla, Marc Chaussidon

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Rapid Condensation of the First Solar System Solids Yves Marrocchi, Johan Villeneuve, Emmanuel Jacquet, Maxime Piralla, Marc Chaussidon Rapid condensation of the first Solar System solids Yves Marrocchi, Johan Villeneuve, Emmanuel Jacquet, Maxime Piralla, Marc Chaussidon To cite this version: Yves Marrocchi, Johan Villeneuve, Emmanuel Jacquet, Maxime Piralla, Marc Chaussidon. Rapid condensation of the first Solar System solids. Proceedings of the National Academy of Sciences of the United States of America , National Academy of Sciences, 2019, 116 (47), pp.23461-23466. 10.1073/pnas.1912479116. insu-02900638 HAL Id: insu-02900638 https://hal-insu.archives-ouvertes.fr/insu-02900638 Submitted on 16 Jul 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Rapid condensation of the first Solar System solids Yves Marrocchia,1, Johan Villeneuvea, Emmanuel Jacquetb, Maxime Pirallaa, and Marc Chaussidonc aCentre de Recherches Pétrographiques et Géochimiques (CRPG), CNRS, Université de Lorraine, UMR 7358, 54501 Vandoeuvre-lès-Nancy, France; bInstitut de Minéralogie, de Physique des Matériaux et de Cosmochimie (IMPMC), CNRS & Muséum national d’Histoire naturelle, UMR 7590, 75005 Paris, France; and cInstitut de Physique du Globe de Paris, Université de Paris, CNRS, 75238 Paris, France Edited by Mark H. Thiemens, University of California San Diego, La Jolla, CA, and approved October 4, 2019 (received for review July 19, 2019) Chondritic meteorites are composed of primitive components between significant condensation fronts should take similarly formed during the evolution of the Solar protoplanetary disk. long (14), so it is often assumed that condensates formed over The oldest of these components formed by condensation, yet little prolonged timescales (4, 15, 16). In contrast, Sugiura et al. is known about their formation mechanism because of secondary (17) inferred from the absence of low-Ca pyroxene on most heating processes that erased their primordial signature. Amoe- AOAs cooling rates >0.02 K/h at the end of olivine conden- boid Olivine Aggregates (AOAs) have never been melted and sation and Komatsu et al. (18) derived 50 K/h from the presence of underwent minimal thermal annealing, implying they might have silica in one unusual AOA. retained the conditions under which they condensed. We per- Stable isotopes may provide insights into the kinetics of gas– formed a multiisotope (O, Si, Mg) characterization of AOAs to solid processes (19–21). Lighter isotopes are more gas-mobile constrain the conditions under which they condensed and the and will thus preferentially impinge a solid grain, giving it an information they bear on the structure and evolution of the Solar isotopically light composition provided that back-evaporation protoplanetary disk. High-precision silicon isotopic measurements has not erased the initial fractionation. However, CAIs com- of 7 AOAs from weakly metamorphosed carbonaceous chon- monly show mass-dependent, heavy Si, Mg, O signatures (22) drites show large, mass-dependent, light Si isotope enrichments diagnostic of partial evaporation of refractory liquids resulting 30 (–9‰ < δ Si < –1‰). Based on physical modeling of condensation from the melting of solar condensates (23)—whose formation within the protoplanetary disk, we attribute these isotopic com- conditions are hereby blurred. positions to the rapid condensation of AOAs over timescales Yet the relatively fine-grained and sometimes porous AOAs 25 of days to weeks. The same AOAs show slightly positive δ Mg have never been melted and have undergone only moderate that suggest that Mg isotopic homogenization occurred during thermal annealing during the evolution of the Solar pro- EARTH, ATMOSPHERIC, AND PLANETARY SCIENCES thermal annealing without affecting Si isotopes. Such short con- toplanetary disk (3, 24), implying they might represent fairly densation times for AOAs are inconsistent with disk transport pristine condensates. Moreover, because AOAs record the timescales, indicating that AOAs, and likely other high-temperature condensation of olivine, which represented 1/3 of CI (Ivuna-like) condensates, formed during brief localized high-temperature chondritic matter (25)—second only to ice in terms of sheer events. mass—they are more representative of the protoplanetary disk than CAIs. However, in situ stable isotopic characterizations of meteorites | condensation | protoplanetary disk | isotopes AOAs have been performed only for oxygen, an element no- toriously subject to poorly understood mass-independent frac- he proto-Sun and its surrounding protoplanetary disk formed tionations within the protoplanetary disk, potentially blurring T4.57 Ga ago from the gravitational collapse of the dense any mass-dependent condensation signal (26, 27). Here, we core of a molecular cloud. Chondrites are primitive meteorites report the oxygen, silicon, and magnesium isotopic composition left over from the evolution of the Solar protoplanetary disk. of Mg-rich olivine grains in AOAs from a set of carbonaceous They comprise chondrules, fine-grained matrix, and the oldest chondrites characterized by minimal thermal metamorphism. known solids of the Solar System (1), refractory inclusions in We use our results to quantify the conditions under which the form of Ca- and Al-rich inclusions (CAIs, millimeter- to primordial dust formed in the Solar System and discuss the centimeter-sized high-temperature complex assemblages of refractory oxides and silicates; ref. 2) and amoeboid olivine Significance aggregates (AOAs, fine-grained aggregates of olivine grains associated with variable proportions of CAI-like materials; ref. Combined O, Si, Mg isotopic measurements of amoeboid olivine 3). The mineralogy of refractory inclusions resembles that of aggregates allow the individual condensation timescales of a the earliest condensates predicted to form from a cooling gas of typical set of the first Solar System solids to be estimated. Our solar composition, with AOAs appearing to be somewhat results indicate formation over days or weeks, much faster than lower-temperature objects than CAIs. This has long upheld the could be inferred from the secular evolution of the Solar pro- notion that the first solids of the Solar System formed by se- toplanetary disk. The oldest solids of the Solar System thus bear quential gas–solid condensation of vaporized presolar matter witness to a turbulent disk with strong thermal heterogeneities. (4–6), although many have undergone subsequent melting events, such as those which produced the ever-mysterious chondrules Author contributions: Y.M. and J.V. designed the study and performed the isotopic mea- (e.g., ref. 7). surements; Y.M., J.V., E.J., M.P., and M.C. discussed the ion probe data; E.J. devised the However, the timescales of condensation and/or partial astrophysical model; Y.M., J.V., E.J., and M.C. wrote the paper. evaporation during formation of AOAs and non-igneous CAIs The authors declare no competing interest. remain largely underconstrained. Mere thermodynamics offer This article is a PNAS Direct Submission. “ ” little insight into the prehistory of the solids and igneous This open access article is distributed under Creative Commons Attribution-NonCommercial- cooling rates estimates refer to melting/crystallization events NoDerivatives License 4.0 (CC BY-NC-ND). (8), not original gas–solid condensation. Al–Mg dating pro- Data deposition: All raw SIMS data, summary of the data, and output of the model can be vides only an upper bound of a few 10s or 100s of millennia for found at https://data.mendeley.com/datasets/dnxgdbzmzk/3. the condensation epoch (9–12), which says little on the for- 1To whom correspondence may be addressed. Email: [email protected]. mation timescales of individual condensates. From an astro- This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10. physical viewpoint, evolution of isotherms should be fairly 1073/pnas.1912479116/-/DCSupplemental. 4 6 slow (on 10 to 10 -y timescales; ref. 13) and random motions First published November 4, 2019. www.pnas.org/cgi/doi/10.1073/pnas.1912479116 PNAS | November 19, 2019 | vol. 116 | no. 47 | 23461–23466 Downloaded at CNRS Trial Access on July 16, 2020 implications on the structure and evolution of the Solar protoplane- waiting times. Thus, each measurement took ∼7 min. Under these condi- tary disk. tions, internal precision on δ29Si and δ30Si was ±0.05 through 0.30‰ and ±0.10 through 0.60‰ (2σ SE), respectively, depending on the sample, Material and Methods and the external reproducibility on δ29Si and δ30Si for the San Carlos ol- ivine was ±0.10‰ and ±0.15‰, respectively (2σ SE). We also analyzed the We surveyed all AOAs in a section each of Kaba (thin section N4075 from the oxygen and magnesium isotopic compositions of olivines in the same Natural History Museum, Vienna, Austria), Northwest Africa (NWA) 5958 AOAs following previously established protocols (see SI Appendix for (thick section NWA 5958–1 from the Muséum national d’Histoire naturelle, technical details). Paris, France) and Miller Range (MIL) 07342 (thick section MIL 07342,9 from the NASA Antarctic Search for Meteorites
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