日本地球惑星科学連合2021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-VC29] 火山の熱水系

2021年6月6日(日) 13:45 〜 15:15 Ch.25 (Zoom会場25)

コンビーナ:藤光 康宏(九州大学大学院工学研究院地球資源システム工学部門)、神田 径(東京工業大学理学院火山流体研究センター)、大場 武(東海大学理学部化学科)、座長:大場 武(東海大学理学部化学科)、神田 径(東京工業大学理学院火山流体研究センター)

14:15 〜 14:30

[SVC29-03] Evolution of the magmatic-hydrothermal system of Mendeleev volcano (Kunashir Island)

*Alexey Andreevich Kotov1、Sergey Zakharovich Smirnov2、Noriyoshi Tsuchiya1、Masaoki Uno1 (1.Graduate School of Environmental Studies, Tohoku University、2.Institute of Geology and Mineralogy SB RAS, Novosibirsk, Russia )


キーワード:Caldera eruptions, Water content, Dacite pumice

Caldera eruption of Mendeleev volcano occurred about 39 thousand years ago on Kunashir Island. The volume of pyroclastic material is estimated at 60 km3, which makes this eruption one of the largest eruptions of the Upper Pleistocene in the southern Kuril Islands. The pumice stones of the caldera eruption are dacitic. The proportion of porphyry phenocrysts in pumice is not higher than 20 vol. %. Phenocrysts are represented by plagioclase, augite, hypersthene, quartz, magnetite, and ilmenite, which are immersed in a glassy groundmass. Pumice stones do not contain amphibole phenocrysts; however, it was found in the form of crystalline inclusions in pyroxenes. Amphibole is Mg-Fe3+ hornblende (Al2O3 7-11 wt. %). To estimate pressures, we used an amphibole geobarometer (Ridolfi et al., 2010). We argue that the amphibole is a relic of a mineral association that formed during the partial melting of crustal metabasites of Kunashir Island. Thus, the estimates of the PT parameters correspond to the process of generation of the melt that participated in the formation of the upper crustal magmatic chamber. The maximum estimates of the PT parameters were about 3 kbar and 920°C. Most of the compositions of amphibole correspond to 1-2 kbar and temperatures of 780 - 890°C. Melts were formed at high fO2 corresponding to the NNO +0.1-1.9 buffer.

Pumice phenocrysts often contain primary glassy melt inclusions (MI). Sometimes these MI’s contain empty shrinkage bubbles. The composition of MI corresponds to low-K2O dacite-rhyodacite. MI’s differ from the bulk rocks by a higher SiO2 content and do not differ in alkali content. The most important part of this study is to determine the content of volatile components in the melts that participated in the caldera eruption. By combining the methods of Raman spectroscopy and the measurement of oxygen by the EPMA EDS, we found that MI’s contain from 4.2 to 7.4 wt. % H2O. At the same time, the water content in the glass of the groundmass does not exceed 4.5 wt% H2O, which indicates significant losses of volatile melts during a caldera eruption. Comparison of the content of volatile components in glasses of the groundmass and in melt inclusions allows us to estimate the amount of volatile components emitted into the atmosphere during a caldera eruption.

Phenocrysts of plagioclase and clinopyroxene also contain primary and pseudo-secondary fluid inclusions (FI). The features of the composition and location of FI’s show that during the evolution the melt degassed. And this degassing is not associated with the final large eruption, as indicated by the presence of pseudo-secondary FI. Also, combined melt inclusions were found. They are represented by melt, trapped non-daughter crystals, and two-phase fluid segregations (liquid H2O and gaseous CO2). These inclusions indicate that the fluid pressure in the chamber could have exceeded the lithostatic one. An additional drop in lithostatic pressure (for example, due to the rise of magma) allowed additional portions of fluid to migrate from the glass of the melt inclusion into these segregations. The data obtained make it possible to accurately describe the evolution of magma from Mendeleev volcano before the caldera eruption and to compare it with other Pleistocene-Holocene calderas of the Southern Kuriles.

References
Ridolfi F., Renzulli A., Puerini M. Stability and chemical equilibrium of amphibole in calc-alkaline magmas: an overview, new thermobarometric formulations and application to subduction-related volcanoes, 2010, Contrib. Mineral. Petrol. V. 160, P. 45–66.