Imaging the dynamics of magma propagation using radiated seismic intensity

B. Taisne; F. Brenguier; N. M. Shapiro; V. Ferrazzini

doi:10.1029/2010GL046068

Imaging the dynamics of magma propagation using radiated seismic intensity

B. Taisne^*, F. Brenguier, N. M. Shapiro, V. Ferrazzini

^*Corresponding author for this work

Institut de physique du globe de Paris

Research output: Contribution to journal › Article › peer-review

98 Citations (Scopus)

Abstract

At shallow depth beneath the Earth's surface, magma propagates through strongly heterogeneous volcanic material. Inversion of buoyancy and/or solidification have strong impacts on the dynamics of propagation without any change of magma supply. In this paper, we study the spatial and time evolution of magma intrusions using induced seismicity. We propose a new method based on ratio analysis of estimates of radiated seismic intensities recorded at different stations during seismic swarms. By applying this method to the January 2010 Piton de la Fournaise volcano eruption, we image complex dike propagation dynamics which strongly differ from a model of constant velocity dike propagation. We provide a new method to image in real time the dynamics of dike propagation and to infer the position of eruptive fissures.

Original language	English
Article number	L04304
Journal	Geophysical Research Letters
Volume	38
Issue number	4
DOIs	https://doi.org/10.1029/2010GL046068
Publication status	Published - Feb 1 2011
Externally published	Yes

ASJC Scopus Subject Areas

Geophysics
General Earth and Planetary Sciences

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abstract = "At shallow depth beneath the Earth's surface, magma propagates through strongly heterogeneous volcanic material. Inversion of buoyancy and/or solidification have strong impacts on the dynamics of propagation without any change of magma supply. In this paper, we study the spatial and time evolution of magma intrusions using induced seismicity. We propose a new method based on ratio analysis of estimates of radiated seismic intensities recorded at different stations during seismic swarms. By applying this method to the January 2010 Piton de la Fournaise volcano eruption, we image complex dike propagation dynamics which strongly differ from a model of constant velocity dike propagation. We provide a new method to image in real time the dynamics of dike propagation and to infer the position of eruptive fissures.",

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AU - Taisne, B.

AU - Brenguier, F.

AU - Shapiro, N. M.

AU - Ferrazzini, V.

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AB - At shallow depth beneath the Earth's surface, magma propagates through strongly heterogeneous volcanic material. Inversion of buoyancy and/or solidification have strong impacts on the dynamics of propagation without any change of magma supply. In this paper, we study the spatial and time evolution of magma intrusions using induced seismicity. We propose a new method based on ratio analysis of estimates of radiated seismic intensities recorded at different stations during seismic swarms. By applying this method to the January 2010 Piton de la Fournaise volcano eruption, we image complex dike propagation dynamics which strongly differ from a model of constant velocity dike propagation. We provide a new method to image in real time the dynamics of dike propagation and to infer the position of eruptive fissures.

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Imaging the dynamics of magma propagation using radiated seismic intensity

Abstract

ASJC Scopus Subject Areas

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