JpGU-AGU Joint Meeting 2020

講演情報

[J] ポスター発表

セッション記号 P (宇宙惑星科学) » P-PS 惑星科学

[P-PS10] 太陽系物質進化

コンビーナ:藤谷 渉(茨城大学 理学部)、松本 恵(東北大学大学院)、小澤 信(東北大学大学院理学研究科地学専攻)、日比谷 由紀(国立研究開発法人海洋研究開発機構 海底資源センター )

[PPS10-P06] 5つのCMコンドライト中のTCIの微細組織観察とCMコンドライト母天体の水質環境の推定

家本 あかね1、*瀬戸 雄介1三宅 亮2 (1.神戸大学大学院理学研究科、2.京都大学大学院理学研究科)

キーワード:炭素質コンドライト、水質変質、トチリナイト

Introduction: CM chondrites are aqueously altered meteorites which contain around 10 wt% H2O in hydrous minerals. TCIs, fine intergrowths of tochilinite (6(Fe0.9S)・5[(Mg,Fe)(OH)2]) and cronstedtite (Fe-bearing serpentine), are one of the characteristic products of CM parent body aqueous alteration. TCIs are considered to be divided into two types based on the textural feature. Type I TCIs are generally found in the chondrules and believed to be altered from iron metal because they often contain kamacite inside [e.g., 1]. Type-II TCIs are found within the matrices. Although several formation processes of type-II have been proposed [e.g., 2,3], the argument has not yet been settled. TCIs potentially provide important information regarding aqueous environments on chondrite parent bodies. Here, we report microtextures of type-II TCIs in five CM chondrites and discuss the formation processes.

Materials and methods: We observed the following five CM chondrites; Cold Bokkeveld (2.2), Nogoya (2.2) , Murray (2.4-2.5), Murchison (2.5) , QUE 97990 (2.6). The numbers in parenthesis are the alteration index for CM chondrites proposed by Rubin et al. (2007) [4], in which the index is defined ranging from 2.6 (less altered) to 2.0 (highly altered). Textural observation and chemical analyses were performed using an SEM-EDS (JEOL, JSM-6480LAII), and nanometer-scale observations using an STEM-EDS (JEOL, JEM-2100F) after processing into thin films using an FIB (FEI, Quanta 3DS).

Results and discussion: In the less altered CM chondrites (QUE 97990 and Murchison), their type-II TCIs showed a similar texture. They are widely distributed in the matrices as compact aggregates of a few hundred nm-sized tochilinite and cronstedtite. From the TEM observations, thin veins of tochilinite were developed inside cracks or cleavages of cronstedtite, suggesting that tochilinite had been crystallized after the formation of cronstedtite. In contrast, the TCIs in Cold Bokkeveld (highly altered) showed core-rim structure. The core region is often rich in mixed layer phase (MLP; alternately stacked phase of tochilinite/cronstedtite layer in nanometer scale), and the rim mainly consists of coarse-grained tochilinite and cronstedtite, which resembles those of the less altered meteorites. Another highly altered meteorite Nogoya (2.2) also has TCIs with zonal texture, where very fine (several tens of nm) and fluffy serpentine rich material is located around core, and toward rim, gradually changed to fibrous cronstedtite and MLP. Murray, intermediately altered CM, has both type of TCIs seen in less and highly altered ones as noted above, indicating Murray was at an intermediate stage during the course of TCIs formation. All observed type-II TCIs in the present study do not include any precursor minerals such as anhydrous silicates or iron metal. TCIs of the two highly altered CM chondrites (Cold Bokkeveld and Nogoya) showed fluffy texture at their core region. These results probably suggest that fluffy type-II TCIs were not formed directly from solid material (like type-I), but crystallized under mobile environments such as water solution. In the case, changes of the fluid condition during the TCI formation resulted in the zonal texture as seen in the highly altered meteorites. The fact that the TCIs in QUE 97990 and Murchison resembles the coarse-grained rim of those in Cold Bokkeveld indicates the two less altered meteorites had experienced aqueous alteration similar to the last stage of aqueous alteration that Cold Bokkeveld had experienced.

References: [1] Tomeoka and Buseck. (1985) Geochimica et Cosmochimica Acta 49:2149–2163. [2] Pignatelli. et al. (2016) Meteoritics & Planetary Science 51:785-805. [3] Lee et al. (2013) Geochimica et Cosmochimica Acta 121:452-466. [4] Rubin et al. (2007) Geochimica et Cosmochimica Acta 71:2361-2382.