JpGU-AGU Joint Meeting 2017

Presentation information

[JJ] Poster

S (Solid Earth Sciences) » S-MP Mineralogy & Petrology

[S-MP44] [JJ] Physics and Chemistry of Minerals

Sun. May 21, 2017 10:45 AM - 12:15 PM Poster Hall (International Exhibition Hall HALL7)

convener:Hiroaki Ohfuji(Geodynamics Research Center, Ehime University), Seiji Kamada(Frontier Research Institute for Interdisciplinary Sciences, Tohoku University)

[SMP44-P11] CaO8 and MgO8 clustering in Grs50Prp50 garnet in diamond-bearing dolomite marble from the Kokchetav Massif

*Tomohiro Takebayashi1, Takeaki Saito2, Kunihiko Sakamaki1, Hiroshi Suzuki2,1, Yoshihide Ogasawara2,1 (1.Department of Earth Sciences, Resources and Environmental Engineering, Graduate school of Creative Science and Engineering, Waseda University, 2.Department of Earth Sciences, Waseda University)

Keywords:Grossular-Pyrope Garnet, Ultrahigh-pressure, diamond, Laser Raman spectroscopy, clustering, Kokchetav

Grossular-pyrope garnet (ca. Grs50Prp50) has long been attracted about crystal chemistry, mixing properties, and P-T stabilities. Many experimental and thermodynamic studies on grossular-pyrope garnet have been conducted (e.g., Ganguly et al., 1996; Geiger, 2013; Du et al., 2016). Garnet having near the Grs50Prp50 composition is extremely rare in nature. Only two occurrences have been reported, so far; (1) xenocrysts in the kimberlite from Garnet Ridge, Arizona (Wang et al., 2000) and (2) diamond-bearing dolomite marble from the Kokchetav UHP Massif, Kazakhstan (e.g., Ogasawara et al., 2000; Sobolev et al., 2001). This strange garnet from the Kokchetav Massif is a main constituent silicate mineral of dolomite marble (P > 6 GPa, T = ca. 1000 °C) and is a main host mineral of abundant microdiamond (Ogasawara et al., 2000; 2005). This garnet is chemically homogeneous and has its composition range: Grs: 43-46, Prp: 39-42, and Alm: 10-16 mol%. The closest composition to Grs50Prp50 is Grs44Prp42Alm10. No exsolution and no symplectite were observed.
We conducted laser Raman spectrometry on this Grs50Prp50 garnet in the Kokchetav UHP dolomite marble. Among the obtained Raman bands at 366, 556, and 903 cm-1, we focused on the band at 366 cm-1 that was assigned to R(SiO4)4-. FWHM of this band was significantly large (24.5 cm-1), compared to those of Prp (14.3 cm-1at 365 cm-1) and Grs (14.0 cm-1 at 372 cm-1). Such a large FWHM of Grs50Prp50 garnet suggested that two kinds of R(SiO4)4- bands corresponding to Grs and Prp were obtained as one overlapped broad band because the peak positions of both bands are very close. The synthesized band from Grs and Prp end-member was well fitted to the observed band.
In the crystal structure of garnet, a SiO4 tetrahedron is surrounded by six dodecahedra XO8 (Geiger, 2013). A SiO4 tetrahedron of grossular surrounded by six CaO8, and that of pyrope by six MgO8. The observed overlapping of two R(SiO4)4- bands corresponding to Grs and Prp indicates two modes for R(SiO4)4- in a single Grs50Prp50 crystal; R(SiO4)4- of SiO4 surrounded by six CaO8 (CaO8 clustering around SiO4) and that by six MgO8 (MgO8 clustering around SiO4). Such clustering stabilized garnet of ca. Grs50Prp50, and could be controlled by two factors: (1) bulk chemistry near Ca:Mg = 1:1 and (2) UHP conditions. No exsolution lamella and no symplectite mean that Grs50Prp50 garnet was stable under low P and T once it formed at high P and T.

Reference
Du, W., Clark, S.M., Walker, D., 2016, American Mineralogist, 101, 193-204.
Ganguly, J., Cheng, W., Tirone, M., 1996, Contributions to Mineralogy and Petrology, 126, 137-151.
Geiger, C.A., 2013, Elements, 9, 447-452.
Ogasawara, Y., 2005, Elements, 1, 91-96.
Ogasawara, Y., Ohta, M., Fukasawa, K., Katayama, I., Maruyama, S., 2000, Island Arc, 9, 400-416.
Sobolev, N.V., Schertl, H.-P., Burchard, M., Shatsky, V.S., 2001, Doklady Earth Science, 380, 791-794.
Suzuki, H., Takebayashi, T., Saito, T., Sakamaki, K., Ogasawara, Y., 2017, JpGU Meeting abstract.
Wang, L., Essene, E.J., Zhang, Y., 2000, American Mineralogist, 85, 41-46.