期刊
GEOCHIMICA ET COSMOCHIMICA ACTA
卷 318, 期 -, 页码 352-365出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.gca.2021.12.002
关键词
Clay minerals; Organic-mineral interaction; Hydrothermal alteration; Asteroids; Carbonaceous chondrites
资金
- Agence Nationale de la Recherche [ANR-16-CE29-0015: RAHIIA_SSOM]
- European Research Council [819587: HYDROMA]
- Paris ile-de-France Region DIM ACAV+ funding (PAR-YUGU)
- Region Ile de France grant SESAME [I-07-593/R]
- INSU-CNRS
- INP-CNRS
- UPMC-Paris 6
- Agence Nationale de la Recherche (ANR) [ANR-07-BLAN-0124-01]
- Chevreul Institute
- European FEDER
- Region Nord-Pas-de-Calais
- CNRS
- CEA
- Region Ile de France
- Departmental Council of Essonne
- Region Centre
The study revealed differences in polymerization reactions of organic materials in the presence or absence of Fe-rich smectitic minerals under simulated asteroid conditions, and the influence of organic materials on the crystallization of minerals. These findings contribute to a better understanding of the interactions between organic materials and minerals in carbonaceous chondrites.
Carbonaceous chondrites contain both soluble and insoluble organic materials (SOM and IOM) which may have been produced in different environments via different processes or share possible genetic relationships. The SOM may have been produced from IOM during hydrothermal episodes on asteroids, and vice versa. The potential role played by the mineral matrix during these episodes (clay minerals of variable crystallinity) remains to be constrained. Here, we exposed a mixture of formaldehyde and glycolaldehyde with ammonia-bearing liquid water together with Fe-rich smectitic minerals to hydrothermal conditions mimicking asteroidal conditions. We used both amorphous gel of smectite or crystalline smectites in order to understand the influence of the crystallinity on the evolution of OM. The organo-mineral experimental residues were characterized at a multiple length scales using X-ray diffraction and microscopy/spectroscopic tools. Results evidence that some IOM polymerizes/condenses in the absence of Fe-rich smectites. Yet, the presence of Fe-rich smectites inhibits this production of IOM. Indeed, the interactions between the SOM and clay surfaces (interlayers or edges) reduce the concentration of SOM available for polymerization/condensation reactions, a necessary step for the production of IOM. In addition, the presence of OM disorganizes the crystallization of the Fe-rich amorphous silicates, leading to smaller crystal sized particles exhibiting a lower permanent charge. This might suggests that the smectite permanent charge distribution may help better constraining the origin and evolution of chondritic clay minerals. Altogether, the present study sheds new light on the organo-mineral interactions having occurred during hydrothermal episodes onto/within chondritic asteroids. Indeed, IOM formation from OMrich aqueous fluids does not occur during the alteration of amorphous silicates. This would mean that IOM is either produced within pockets free of clay minerals or initially accreted as IOM-rich grain. Last, about -50 wt% of the initial C could not be removed from the clay minerals at the end of the experiments using classical solvent extraction protocols, demonstrating that a high fraction of the SOM in carbonaceous chondrites may have been overlooked. (c) 2021 Elsevier Ltd. All rights reserved.
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