日本地球惑星科学連合2016年大会

講演情報

ポスター発表

セッション記号 S (固体地球科学) » S-VC 火山学

[S-VC48] 火山・火成活動と長期予測

2016年5月22日(日) 17:15 〜 18:30 ポスター会場 (国際展示場 6ホール)

コンビーナ:*及川 輝樹(国研)産業技術総合研究所 活断層・火山研究部門)、長谷川 健(茨城大学理学部地球環境科学コース)、三浦 大助(一般財団法人 電力中央研究所 地球工学研究所 地圏科学領域)、石塚 吉浩(産業技術総合研究所活断層・火山研究部門)、下司 信夫(産業技術総合研究所 活断層・火山研究部門)

17:15 〜 18:30

[SVC48-P17] 黒曜石溶岩のマグマ上昇・脱ガス過程
—溶岩構造、岩石組織、含水量分布に基づく考察—

*佐野 恭平1佐藤 鋭一2後藤 芳彦3和田 恵治4 (1.遠軽町白滝ジオパーク、2.神戸大学、3.室蘭工業大学、4.北海道教育大学旭川校)

キーワード:黒曜石、開放系脱ガス、含水量

Structures of obsidian lava are mainly divided into two regions; obsidian and rhyolite. These are defined based on the differences in appearance of hand specimens and rock texture. Rhyolite has perlitic cracks in the glass and contains some amounts of crystalline materials, namely, spherulite and lithophysae, whereas obsidian includes no such material at all.
Recent observation on Cordon Caulle (Chile, 2011–12) reported that explosive-effusive hybrid activity (Schipper et al., 2013), and we can consider that these differences are reflecting heterogeneous processes such as vesiculation and outgassing in volcanic conduit, and forms obsidian and rhyolite. In order to reveal such heterogeneous vesiculation and outgassing processes of viscous magmas, we performed water concentration analyses with comparing rock texture of samples from Sanukayama (SN) obsidian lava at Ko-zu island and Akaishiyama (AK) obsidian lava at Shirataki, Hokkaido.
A cross-section of the SN lava shows the following sequence from the bottom up: a lower rhyolite region (SN-LRhy), a lower boundary banded region (SN-LBB: 40 [m]) of obsidian and rhyolite, obsidian region (SN-Ob), upper boundary banded region (SN-UBB) and a clinker region (SN-CL) that is composed of vesiculated rhyolite and fine matrix. The SN obsidian is aphyric and contains microlites of plagioclase, biotite and oxides. Phenocrysts are plagioclase and biotite.
AK lava is characterized by well-growth spherulite. A cross-section of the AK lava is the following sequence from the bottom: lower obsidian region (AK-LOb), lower boundary banded region (AK-LBB), rhyolite region (AK-Rhy), upper boundary banded region (AK-UBB) and Upper obsidian region (AK-UOb). The AK obsidian contains oxide microlite, and no phenocrysts are contained. At AK lava, we can observe flow bands which are composed of the cm-scale spherulites in BB and Rhy regions. Sometimes spherulites include the obsidian particle. We can also observe the tuffisite structure.
The water concentration was determined using Karl Fischer Titration at the Hokkaido University of Education at Asahikawa. First, we powdered rock samples making sure that there were no crystal fragments. Next, we handpicked powders with an accuracy of ± 103 g for titration. The samples were heated to 120 [°C] for about 1 h to eliminate all adsorbed H2O. Finally, we heated the samples to a temperature of 1000 °C to calculate the amount of dissolved water (Westrich, 1987). The titrations were finished when Time-Water amount slope become flat. The duration of analyses was up to 1[h].
Water concentrations in SN samples are following; 0.07 – 0.27 [wt.%] in L-Rhy, 0.22 – 0.99 [wt.%] in L-BB, 0.01 – 0.29 in Ob, 0.01 – 0.21 [wt.%] in Ob, 0.08 – 3.06 [wt.%] in rhyolite region, respectively. The degree of hydration is higher in clinker region than lower rhyolite. Shields et al. (2016) suggested that the amounts of hydration of rhyolite lava samples have positive correlation with the connected vesicularity. According to their study, connected vesicules were highly developed in upper regions.
Water concentrations in AK obsidian were in the range of 0.01 – 0.03 [wt.%], and no systematic change relating to lava structure can be observed. Spherulite shows 1.1 [wt. %] water concentration. We can consider that this value reflects that flow band structure, which is composed of spherulites, has connected vesicularity.
We compared the water concentration profile with lava structure and rock texture at SN and AK lava. Water concentration profiles give us the useful information to reveal the vesiculation and outgassing processes in obsidian lava.