日本地球惑星科学連合2014年大会

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インターナショナルセッション(口頭発表)

セッション記号 S (固体地球科学) » S-CG 固体地球科学複合領域・一般

[S-CG08_29AM2] Collision, Subduction, and Metamorphic processes-II

2014年4月29日(火) 11:00 〜 12:30 311 (3F)

コンビーナ:*Ur Rehman Hafiz(Department of Earth and Environmental Sciences, Graduate School of Science and Engineering, Kagoshima University)、Tatsuki Tsujimori(Institute for Study of the Earth's Interior, Okayama University)、Kazuaki Okamoto(Faculty of Education, Saitama University)、座長:岡本 和明(埼玉大学教育学部地学)、西山 忠男(熊本大学自然科学研究科理学専攻地球環境科学講座)

12:10 〜 12:30

[SCG08-10] 沈み込み起源の超高圧クロミタイト:西彼杵変成岩の例

*西山 忠男1森部 陽介1石丸 聡子1荒井 章司2森 康3重野 未来3 (1.熊本大学自然科学研究科、2.金沢大学地球科学教室、3.北九州市立いのちのたび博物館)

キーワード:マイクロダイヤモンド, 超高圧クロミタイト, 沈み込み帯, 西彼杵変成岩, 超高圧変成岩

Ultrahigh-pressure (UHP) chromitite from the Luobsa Ophiolite in non UHP terrane has been an enigima because of its peculiar occurrence. We newly found a UHP chromitite from serpentinite in the Nishisonogi metamorphic rocks (NMR), a member of the Nagasaki Metamorphic Rocks, in Western Kyushu, following our finding1 of it from the Higo Metamorphic Rocks (HMR), Central Kyushu. The UHP chromitite from NMR documents well a fluid -chromite interaction, showing partial graphitization of microdiamond. Such a fluid - chromite interaction is not observed in HMR chromitite. The NMR are high P/ T ( epidote-glaucophane schist subfacies ) metamorphic rocks of Cretaceous in age, mainly consisting of pelitic and psammitic schists intercalating with minor basic schists2. The peak metamorphic condition of the crystalline schists is estimated as 1.4 GPa and 520 oC by an assemblage of garnet with inclusions of chloritoid and omphacite, glaucophane, paragonite, and phengite in a garnet galucophanite3. Serpentinite and serpentinite melanges occur as elongated bodies or lenses concordant with schistosity trending N-S of the country schists1. Jadeitite and omphacitite occur as tectonic blocks in the serpentinite melange, showing the peak condition of 1.5 GPa and 500 oC by coexistence of jadeite and quartz4. Microdiamond - bearing chromitite was found from serpentinite in a melange at Ooseto Town, Saikai City. Chromitite occurs as a thin layer several cm thick and meter-size long in a serpentinite with numerous magnesite (or ankerite) veins. The layer is strongly deformed to show a schlieren - like structure. The serpentinite consists of fine-grained antigorite with no relics of olivine and pyroxenes. The chromitite consists of an aggregate of rounded and fractured chromite crystals with small amounts of talc and magnesite as a matrix and veins. Microdiamond occurs as aligned crystals in narrow zones ranging from a few μm to several tens of μm in chromite. Chromite is zoned, consisting of Mg-rich core (Mg0.33Fe2+0.65Mn0.03)(Cr0.84Al0.12Fe3+0.04)2O4 and Fe-rich rim (Mg0.06Fe2+0.89Zn0.02Mn0.03)(Cr0.85Al0.12Fe3+0.04)2O4. The microdiamond - bearing zones are conspicuously richer in Fe2O3 [ (Mg0.03Fe2+0.94Mn0.04Zn0.01)(Cr0.67Ti0.01Fe3+0.310)2O4], observed as a brighter zone in a BSE image, than other part of chromite in the same grain. The network -like distribution of the zones clearly indicates fluid infiltration associated with the following exchange reaction of trivalent cations between chromite and the fluid: Cr3+ + Al3+( in chromite ) = Fe3+( in fluid) Microdiamond occurs either as polyhedral or as platy crystals, 1 to several μm across. Identification of diamond was carried out with an energy dispersive X-ray spectroscopy (EDS) analysis (carbon peak) and Raman spectroscopy with a He-Ne laser. We observed a broad Raman peak at 1331 cm-1, which is comparable to the peak (1332 cm-1) characteristic of diamond. Graphite peak at about 1600 cm-1 is also observed, showing partial graphitization of microdiamond. These lines of evidence shows that the fluid infiltration may have occurred after inclusion of microdiamond. It is quite astonishing that microdiamond is preserved in such a completely serpentinized ultramafic rock. Chromite can be a good container of microdiamond to prevent graphitization during geologically long duration of exhumation and serpentinization. Our finding suggests the subduction origin of UHP chromitite from NMR rather than mantle migration origin5 in the case of the Luobusa Ophiolite.References 1. Nishiyama. T., Shiosaki, D., Eguchi, H., and Yoshiasa, A. JpGU Meeting, S-MP46 (2014);2. Nishiyama, T. Mem. Geol. Soc. Japan 33, 237-257 (1989) ;3. Moribe, Y. unpublished Mc thesis, Kumamoto University (2014);4. Shigeno, M., Mori, Y.,