日本地球惑星科学連合2014年大会

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セッション記号 S (固体地球科学) » S-VC 火山学

[S-VC54_1AM1] 火山・火成活動とその長期予測

2014年5月1日(木) 09:00 〜 10:45 411 (4F)

コンビーナ:*及川 輝樹(独)産業技術総合研究所 地質情報研究部門)、三浦 大助(財団法人電力中央研究所 地球工学研究所 地圏科学領域)、長谷川 健(茨城大学理学部地球環境科学コース)、下司 信夫(産業技術総合研究所 地質情報研究部門)、石塚 吉浩(産業技術総合研究所地質情報研究部門)、座長:安井 真也(日本大学文理学部)、吉本 充宏(北海道大学大学院理学研究院)

10:15 〜 10:30

[SVC54-P14_PG] 阿蘇火山、高野尾羽根流紋岩溶岩に発達する破砕性流理の起源と変形過程

ポスター講演3分口頭発表枠

*古川 邦之1金丸 龍夫2宇野 康司3 (1.愛知大学経営学部、2.日本大学文理学部地球システム科学科、3.岡山大学大学院教育学研究科)

キーワード:流紋岩, 溶岩, 流理, 火道, 阿蘇

In this study, we showed that the clastic flow bands, which are developed in the Takanoobane rhyolite lava, were formed by shear fracturing of the high viscous magma within the shallow conduit. The flow bands broke up into the small particle-rich flow lines, which are ubiquitously observed in obsidian lavas.
The Takanoobane rhyolite lava (TR lava) is located at the Aso caldera in the middle of Kyushu Island in SW Japan. The lava is effused at 51+/-5 ka (Matsumoto et al., 1991). The thickness, estimated volume, and bulk rock chemistry of TR lava are 60-90 m, 0.14 km3 (Miyabuchi et al., 2004), and 71-72 SiO2 wt.% (Furukawa, 2006), respectively. In this study, we examined two drill cores (AVL1 and AVL4) provided by the Aso Volcanological Laboratory. Both drill holes penetrated the proximal part of TR lava. TR lava is composed of an inner crystalline part and marginal glassy parts.
The black to dark gray colored flow bands within a few millimeters thick are concentrated around the boundary between crystalline part and basal obsidian. The bands are composed of clastic materials with a diameter below a few mm. The clastic materials are composed of glassy lithics and minerals. Some clasts are rounded and fluidal shapes and show different textural occurrences from the surrounding rhyolite. The chemical compositions of the glassy lithics and those of glassy matrix of the surrounding rhyolite are slightly different. Within the bands, the streak texture, which is defined by difference of clasts and microlite contents, is conspicuous.
The differences in texture and chemical compositions between the clasts in the bands and surrounding rhyolite indicate that the clastic bands were not formed by autobrecciation within the lava. These observations indicate that the clastic bands are likely to be formed by shear fracturing of the high viscous magma within the shallow conduit such as Tuffen et al. (2003). The fractures would become pathway of the volcanic gasses, and the clasts were transported by the gas transport. The streak texture within the bands is interpreted as sedimentary structures, which were formed by gas transportation of clasts through fracture system. The rounded and fluidal shapes of the clasts indicate that the fracturing occurred when the conduit magma was enough hot. The clastic bands consequently break up and disappear. The bands show progressive loosening along the individual streak, where will be the structural weakness. Consequently, the streak develops into the individual thin bands. The small particles, such as glass particles, microlites and lithics, are released from margin of the clastic bands to the surrounding rhyolite. Since the high viscosity of the lava inhibits their homogenization, the particles are likely to be aligned along the flow line. The clastic flow bands, originated from shear fracturing, will thoroughly break up via this process. Our results mean that the clastic flow bands developed within silicic lavas is important for understanding of the shallow conduit system of silicic magma.