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Hydrothermal and Magmatic System of a Volcanic Island Inferred From Magnetotellurics, Seismicity, Self‐potential, and Thermal Image: An Example of Miyakejima (Japan)

Marceau Gresse, Makoto Uyeshima, Takao Koyama, H. Häse, Koki Aizawa, Yusuke Yamaya, Yuichi Morita, Derek Weller, Tawat Rung‐Arunwan, Takayuki Kaneko, Yoichi Sasai, J. Zlotnicki, Tsuneo Ishido, Hideki Ueda, Maki Hata

2021Journal of Geophysical Research Solid Earth33 citationsDOIOpen Access PDF

Abstract

Abstract Phreatic and phreatomagmatic eruptions represent some of the greatest hazards occurring on volcanoes. They result from complex interactions at a depth between rock, water, and magmatic fluids. Understanding and assessing such processes remain a challenging task, notably because a large‐scale characterization of volcanic edifices is often lacking. Here we focused on Miyakejima Island, an inhabited 8‐km‐wide stratovolcano with regular phreatomagmatic activity. We imaged its plumbing system through a combination of four geophysical techniques: magnetotellurics, seismicity, self‐potential, and thermal image. We thus propose the first comprehensive interpretation of the volcanic island in terms of rock properties, temperature, fluid content, and fluid flow. We identify a shallow aquifer lying above a clay cap (<1 km depth) and reveal its relation with magmatic‐tectonic features and past eruptive activity. At greater depths (2–4.5 km), we infer a seismogenic resistive region interpreted as a magmatic gas‐rich reservoir (≥370°C). From this reservoir, gases rise through a fractured conduit before being released in the fumarolic area at ∼180°C. During their ascent, these hot fluids cross a ∼1.2‐km‐long liquid‐dominated zone causing local steam explosions. Such magmatic‐hydrothermal interaction elucidates (i) the origin of the long‐period seismic events and (ii) the mixing mechanism between magmatic and hydrothermal fluids, which was previously observed in the geochemical signature of fumaroles. Our results demonstrate that combining multidisciplinary large‐scale methods is a relevant approach to better understand volcanic systems, with implications for monitoring strategies.

Topics & Concepts

GeologyFumarolePhreatomagmatic eruptionVolcanoPhreaticPhreatic eruptionInduced seismicityHydrothermal circulationMagnetotelluricsExplosive eruptionPetrologyGeophysicsSeismologyGeochemistryDiatremeStratovolcanoTectonicsAquiferEarth scienceMagmaPyroclastic rockGroundwaterMantle (geology)EngineeringElectrical resistivity and conductivityGeotechnical engineeringElectrical engineeringKimberliteGeophysical and Geoelectrical MethodsGeophysical Methods and ApplicationsSeismic Waves and Analysis
Hydrothermal and Magmatic System of a Volcanic Island Inferred From Magnetotellurics, Seismicity, Self‐potential, and Thermal Image: An Example of Miyakejima (Japan) | Litcius