Minor and trace element concentrations in adjacent kamacite and taenite in the Krymka chondrite |
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| Authors: | N Meftah S Mostefaoui A Jambon E H Guedda S Pont |
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| Affiliation: | 1. Faculté des Mathématiques et des Sciences de la Matière, Université Kasdi Merbah, Ouargla, Algeria;2. Sorbonne Universités ISTEP UMR 7193, UPMC, Paris Cedex 05, France;3. Laboratoire LEVRES et Faculté des Sciences et technologie, Université d'El‐Oued, El‐Oued, Algeria;4. IMPMC, Muséum National d'Histoire Naturelle, Paris, France |
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| Abstract: | We report in situ NanoSIMS siderophile minor and trace element abundances in individual Fe‐Ni metal grains in the unequilibrated chondrite Krymka (LL3.2). Associated kamacite and taenite of 10 metal grains in four chondrules and one matrix metal were analyzed for elemental concentrations of Fe, Ni, Co, Cu, Rh, Ir, and Pt. The results show large elemental variations among the metal grains. However, complementary and correlative variations exist between adjacent kamacite‐taenite. This is consistent with the unequilibrated character of the chondrite and corroborates an attainment of chemical equilibrium between the metal phases. The calculated equilibrium temperature is 446 ± 9 °C. This is concordant with the range given by Kimura et al. (2008) for the Krymka postaccretion thermal metamorphism. Based on Ni diffusivity in taenite, a slow cooling rate is estimated of the Krymka parent body that does not exceed ~1K Myr?1, which is consistent with cooling rates inferred by other workers for unequilibrated ordinary chondrites. Elemental ionic radii might have played a role in controlling elemental partitioning between kamacite and taenite. The bulk compositions of the Krymka metal grains have nonsolar (mostly subsolar) element/Ni ratios suggesting the Fe‐Ni grains could have formed from distinct precursors of nonsolar compositions or had their compositions modified subsequent to chondrule formation events. |
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