A resistivity cross-section of Usu volcano, Hokkaido, Japan, by audiomagnetotelluric soundings

Ogawa, Yasuo; Matsushima, Nobuo; Oshima, Hiromitsu; Takakura, Shinichi; Utsugi, Mitsuru; Hirano, Kenkichi; Igarashi, Muneo; Doi, T.

doi:10.1186/bf03352120

Cited by 38 publications

(28 citation statements)

References 5 publications

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“…More recently, MT measurements revealed the underground structure of Usu volcano (Nishida et al, 1996;Ogawa et al, 1998). Figure 2 shows a two-dimensional resistivity section crossing Usu volcano from northeast to southwest (Matsushima et al, 2002).…”

Section: Shallow Intrusion Of the 1977 Eruptionmentioning

confidence: 99%

“…Kagiyama, 1984), and the volume of heat source was estimated (Matsushima, 1992). The 1977 intrusion was imaged by a recently conducted magnetotelluric study (Ogawa et al, 1998;Matsushima et al, 2002). Effective permeabilities and the hydrological structure of Usu volcano were estimated using wells drilled for hot spring exploitation at the foot of the volcano (Oshima and Matsushima, 1999).…”

Section: Introductionmentioning

confidence: 99%

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Mathematical simulation of magma-hydrothermal activity associated with the 1977 eruption of Usu volcano

Matsushima

2014

Earth Planet Sp

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During the 1977 eruption of Usu volcano, magma was emplaced at shallow crust. This intrusion induced fumarole activity immediately after the eruption. Based on the repeated thermal observations, the amount of heat discharged by this thermal activity is estimated to be 2 × 10 17 J. The corresponding volume of the intrusion is 6 × 10 7 m 3 . The inferred intrusion volume is comparable to the volume of the resistive block beneath the major faults formed by this eruption, which was interpreted as a cooled intrusion on the basis of recently conducted MT surveys. The heat discharge rate is a surface boundary condition for an underlying magma hydrothermal system. A mathematical simulation, which accounts for multiphase mass and heat transport within a porous media, is conducted to reproduce the thermal activity of Usu volcano. The simulation incorporates the supply of latent heat by solidifying magma and heat transfer by degassing. Permeability conditions are important factors to fit the simulated heat discharge rate with the observation. Increased permeability of surrounding formations causes early appearance and high amplitude of surface heat discharge rate and reduced permeability causes opposite effect. The intrusion permeability has a strong influence on the surface thermal activity. High permeability is needed for the early appearance of the surface heat discharge rate, although it results in the maximum intrusion temperature that is much lower than the observed fumarolic temperature. To avoid the inconsistency, temperature dependent permeability is used in the simulation. The inside of the intrusion with the temperature dependent permeability that has low initial values and the high permeable margin are supposed to satisfy the conditions of the observed surface heat discharge rate and fumarolic temperature.

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Section: Shallow Intrusion Of the 1977 Eruptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mathematical simulation of magma-hydrothermal activity associated with the 1977 eruption of Usu volcano

Matsushima

2014

Earth Planet Sp

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“…Katsui et al (1985) performed a topographic survey around the summit area to estimate the location of the magma that swelled Usu-Shinzan and discussed the magma intrusion process beneath Usu-Shinzan. Later, the magma body was clearly imaged at a depth of around sea level by magnetotelluric surveys (Matsushima et al, 2001, Ogawa et al, 1998. While a shallow part of the volcano to depths of 2-4 km is a conspicuous conductor (1-500 ・・m), a resistive block of 500-1000 m is situated beneath Usu-Shinzan at depths of 300-500 m below sea level (Matsushima et al, 2001).…”

Section: Recent Eruptions Of Usu Volcanomentioning

confidence: 99%

“…The hypocenters of the precursory earthquakes of the 2000 eruption were mainly located at depths of 2-3.5 km below sea level (Onizawa et al, 2007). The shallow intrusion of magma during the 1977-1982 eruption was estimated under Usu-Shinzan by magnetotelluric surveys (Ogawa et al, 1998, Matsushima et al, 2001.…”

Section: -2 Interpretation Of the Crustal Activity Under The Summitmentioning

confidence: 99%

Inter-eruptive volcanism at Usu volcano: Micro-earthquakes and dome subsidence

Aoyama

Onizawa

Kobayashi

et al. 2009

Journal of Volcanology and Geothermal Research

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“…In particular, we have already used the MT method to evaluate the large-scale subsurface resistivity structure present within the seismogenic zone beneath the Japanese Archipelago Island Arc system (Ogawa et al, 2001;Uyeshima et al, 2005;Yoshimura et al, 2009), and to evaluate the smaller-scale (shallow) resistivity structure beneath a number of historically active Japanese volcanoes (Ogawa et al, 1998;Hase et al, 2005;Aizawa et al, 2009b;Kanda et al, 2010).…”

Section: Magnetotelluric Monitoringmentioning

confidence: 99%

Magnetotelluric and temperature monitoring after the 2011 sub-Plinian eruptions of Shinmoe-dake volcano

et al. 2013

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Three sub-Plinian eruptions took place on 26-27 January 2011 at Shinmoe-dake volcano in the Kirishima volcanic group, Japan. During this event, GPS and tiltmeters detected syn-eruptive ground subsidence approximately 7 km to the WNW of the volcano. Starting in March 2011, we conducted broad-band magnetotelluric (MT) measurements at a site located 5 km NNW of the volcano, beneath which the Shinmoe-dake magma plumbing system may exist. In addition, temperature monitoring of fumaroles and hot-springs near the MT site was initiated in July 2011. Our MT data record changes in apparent resistivity of approximately ±5%, along with a ±1• phase change in the off-diagonal component of the impedance tensor (Z xy and Z yx ). Using 1-D inversion, we infer that these slight changes in resistivity took place at relatively shallow depths of only a few hundred meters, at the transition between a near-surface resistive layer and an underlying conductive layer. Resistivity changes observed since March 2012 are correlated with the observed temperature increases around the MT monitoring site. These observations suggest the existence beneath the MT site of pathways which enable volatile escape.

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A resistivity cross-section of Usu volcano, Hokkaido, Japan, by audiomagnetotelluric soundings

Cited by 38 publications

References 5 publications

Mathematical simulation of magma-hydrothermal activity associated with the 1977 eruption of Usu volcano

Mathematical simulation of magma-hydrothermal activity associated with the 1977 eruption of Usu volcano

Inter-eruptive volcanism at Usu volcano: Micro-earthquakes and dome subsidence

Magnetotelluric and temperature monitoring after the 2011 sub-Plinian eruptions of Shinmoe-dake volcano

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