日本地球惑星科学連合2015年大会

講演情報

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-IT 地球内部科学・地球惑星テクトニクス

[S-IT06] Early Earth - from accumulation to formation -

2015年5月25日(月) 11:00 〜 11:45 303 (3F)

コンビーナ:*坂巻 竜也(東北大学大学院理学研究科)、鈴木 昭夫(東北大学大学院理学研究科地学専攻)、鎌田 誠司(東北大学大学院理学研究科)、Bjorn Mysen(Geophysical Laboratory, Carnegie Inst. Washington)、座長:坂巻 竜也(東北大学大学院理学研究科)

11:33 〜 11:36

[SIT06-P02] Jadeite in shocked meteorites: various textures and formation processes

ポスター講演3分口頭発表枠

*小澤 信1宮原 正明2大谷 栄治1伊藤 嘉紀1鈴木 昭夫1木村 眞3Olga N. Koroleva4Konstantin Litasov5Nikolay P. Pokhilenko5 (1.Department of Earth Science, Graduate School of Science, Tohoku University, Sendai 980-8578, Japan、2.Department of Earth and Planetary Systems Science, Graduate School of Science, Hiroshima University,、3.Faculty of Science, Ibaraki University, Mito 310-8512, Japan、4.Institute of Mineralogy, UB RAS, Miass, 456317, Russia、5.V. S. Sobolev Institute of Geology and Mineralogy, SB RAS, Novosibirsk, 630090, Russia)

キーワード:jadeite, meteorite, impact, high-pressure mineral, shock melt vein, formation mechanism

Introduction
Collision of materials is one of the most fundamental processes in planet formation of the early solar system. Heavily-shocked meteorites sometimes contain high-pressure minerals, which provide important constraints on the nature of the impact events. Jadeite is a high-pressure mineral identified in various types of meteorites such as H, L and LL chondrites, and Martian meteorites [1-8]. Here, we show various occurrences of jadeite observed in shocked meteorites, and discuss the conditions and mechanisms of jadeite formation.

Results and Discussions
Heavily-shocked ordinary chondrites (H, L and LL) were mainly observed in our studies. They consist of chondritic host-rock and pervasive shock-induced melt veins (SMVs). Jadeite is usually identified in fragments of the host-rock entrained to the SMVs. Albitic feldspar grains in these fragments have been replaced by jadeite plus amorphous material.
A variety of texture was observed in jadeite-bearing grains of Sahara 98222 L6 chondrite, such as “particle-like”, “stringer-like”, and “polycrystalline-like” phases [4]. Similar textures were also reported in jadeite-bearing grains of other L and H ordinary chondrites [5], and shocked rocks from Ries crater, Germany [7]. Detailed TEM observations by Miyahara et al. [5] clarified that these jadeite-bearing grains consist of massive or network-like assemblages of jadeite crystals and interstitial amorphous (or poorly-crystallized) materials. Bulk chemical compositions of the jadeite-bearing grains are almost identical to that of albitic feldspar in the host-rocks. Therefore, the jadeite described above is considered to have formed by solid-state reactions.
On the other hand, we recently found a new occurrence of jadeite in Chelyabinsk LL5 chondrite [8]. Needle-like or skeletal-rhombic crystals of jadeite coexist with amorphous material. The bulk chemical compositions of the jadeite-bearing grains are different (more K-rich) from that of albitic feldspar in the host-rock. In addition, jadeite-rich part is enriched in Na, whereas the amorphous part is highly enriched in K. The significant element migrations appear to be difficult in solid-state reactions during a short duration of an impact. Thus, jadeite in Chelyabinsk meteorite is considered to have crystallized from feldspathic melt.
It is experimentally revealed that albite dissociate into jadeite plus silica phase over 3 GPa, and jadeite can be stable at 3-19 GPa as a liquidus or subsolidus phase [9-14]. The two types of jadeite formation (from solid or melt) were probably caused by different temperature conditions. For the jadeite formed by solid-state reactions, the temperature is considered to have been lower than at least 1400 ℃, the melting temperature of albite at 3 GPa [10,11]. For the jadeite formed from melt, the temperature could have been higher than 1400 ℃. The different textures and chemical compositions of the jadeite-bearing grains reflect different P-T-t (Pressure-Temperature-time) conditions during the impact events on different parent bodies of the meteorites.

References
[1] Kimura et al. (2000) Meteorit. Planet. Sci. 35, A87-A88.
[2] Kimura et al. (2001) Meteorit. Planet. Sci. 36, A99.
[3] Ohtani et al. (2004) Earth Planet. Sci. Lett. 227, 505-515.
[4] Ozawa et al. (2009) Meteorit. Planet. Sci. 44, 1771-1786.
[5] Miyahara et al. (2013) Earth Planet. Sci. Lett. 373, 102-108.
[6] El Goresy et al. (2013) Lunar Planet. Sci. Conf. 44, 1037.
[7] James (1969) Science 165, 1006-1008.
[8] Ozawa et al. (2014) Sci. Rep. 4, 5033.
[9] Birch & LeCompte (1960) Am. J. Sci. 258, 209-217.
[10] Boyd & England (1963) J. Geophys. Res. 68, 311-323.
[11] Bell & Roseboom, Jr (1969) in Pyroxenes and Amphiboles: Crystal Chemistry and Phase Petrology,151-161.
[12] Liu (1978) Earth Planet. Sci. Lett. 37, 438-444.
[13] Yagi et al. (1994) Phys. Chem. Min. 21, 12-17.
[14] Tutti (2007) Phys. Earth Planet. Int. 161, 143-149.