Laize-Générat L., Soussaintjean L., Poch O., Bonal L., Savarino J., Caillon N., Ginot Patrick, Vella A., Lamothe A., Elazzouzi R., Flandinet L., Vacher L., Gounelle M., Bizzaro M., Beck P., Quirico E., Schmitt B. (2024). Nitrogen in the Orgueil meteorite : abundant ammonium among other reservoirs of variable isotopic compositions. Geochimica et Cosmochimica Acta, 387, p. 111-129. ISSN 0016-7037.
Titre du document
Nitrogen in the Orgueil meteorite : abundant ammonium among other reservoirs of variable isotopic compositions
Année de publication
2024
Auteurs
Laize-Générat L., Soussaintjean L., Poch O., Bonal L., Savarino J., Caillon N., Ginot Patrick, Vella A., Lamothe A., Elazzouzi R., Flandinet L., Vacher L., Gounelle M., Bizzaro M., Beck P., Quirico E., Schmitt B.
Source
Geochimica et Cosmochimica Acta, 2024,
387, p. 111-129 ISSN 0016-7037
Nitrogen, because of its abundance and variety of carrier phases, is a unique tracer of physico-chemical processes occurring throughout star and planet formations. The refractory organic matter is commonly considered as the main carrier of nitrogen in the most primitive objects of our Solar System. However, nitrogen in the form of ammonium (NH4+) was observed in the Ivuna-type carbonaceous (CI) chondrites Alais in 1834, and Orgueil just after its fall in 1864, as well as more recently on Ceres, comet 67P/Churyumov-Gerasimenko, and possibly on some asteroids. In the present study, we have measured the nitrogen content and isotopic composition in various nitrogen-bearing phases of several samples of the Orgueil meteorite, with different degrees of terrestrial weathering. Water-soluble NH4+ is present in Orgueil at a mean concentration of 0.07 +/- 0.01 wt%, with a mean isotopic composition of delta N-15 = +72 +/- 9 parts per thousand (N-14/N-15 = 254 +/- 2), confirming its extra-terrestrial origin. In the most terrestrially altered sample of Orgueil that we analysed, the isotopic composition is delta N-15 = +50 +/- 12 parts per thousand (N-14/N-15 = 259 +/- 3). NH4+ is in species that are thermally stable up to 383 K, possibly ammonium inorganic/organic salts and ammoniated phyllosilicates. We also show that the nitrogen in Orgueil is distributed among the insoluble organic matter (IOM) (35 +/- 5 %), ammonium (27 +/- 5 %), and other minor water-soluble species (e.g., nitrate, amines etc.: < 6 %). The remaining nitrogen (34 +/- 14 %) is mainly in an unidentified organic matter (UOM), which may be IOM lost during its extraction and/or acid hydrolysable functional groups bounded to the IOM and/or organic nitrogen trapped within minerals. The three main carriers of nitrogen in Orgueil have delta N-15 (and N-14/N-15) values of +32 +/- 1 parts per thousand (264 +/- 0.3) for IOM, +39 +/- 16 parts per thousand (262 +/- 4) for UOM, and +72 +/- 9 parts per thousand (254 +/- 2) for NH4+. Although IOM and NH4+ have significantly different delta N-15, we cannot exclude that these phases could be compositionally related because IOM is heterogeneous in N-15. Ammonium could have been produced via heating and/or aqueous alteration processes of organic matter in the CI parent body. Alternatively, or additionnally, ammonium could be a tracer of the accretion and/or later deposit of NH3 ice, NH3 hydrates, and/or NH4+ salts on the CI parent body. As shown by previous studies, Ryugu grains sampled by the Hayabusa2 mission (JAXA) have heterogeneous compositions at the millimeter scale, with nitrogen concentrations and delta N-15 similar or lower than Orgueil, possibly because of different parent body processing. The present study suggests that the lack or loss of N-15-rich NH4+ in some Ryugu grains may explain some of these differences with Orgueil.
Plan de classement
Géologie et formations superficielles [064]
Localisation
Fonds IRD [F B010092183]
Identifiant IRD
fdi:010092183
