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Volcanic Earthquakes. Seismic Swarms: A Case Study EPSC 330 Presented by Fabien Rasselet April 4 th , 2007. Volcanic vs. Tectonic Seismicity. Seismicity that precedes, accompanies and follows volcanic eruptions and magmatic intrusions.
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Volcanic Earthquakes Seismic Swarms: A Case Study EPSC 330 Presented by Fabien Rasselet April 4th, 2007
Volcanic vs. Tectonic Seismicity • Seismicity that precedes, accompanies and follows volcanic eruptions and magmatic intrusions. • # of earthquakes are higher than in an average strength (shear) crust. • Hot fluids (magma) and low rock strengths lead to numerous, simultaneous small events (M=I; not felt) • Events occur at depths of 1-9 km. • Events occur as “swarms” as opposed the tectonic mainshock-aftershock sequence.
Variety of Volcanic Earthquakes • A - High frequency events (volcano-tectonic) • B - Hybrid events • C,F - Long Period (Low Frequency) Events • E - Explosion Quake • D,G,H - Volcanic Tremors (McNutt et al., 1995)
Defined as numerous earthquakes of the same size occurring in a small volume. Figure shows # of events/ unit time (N) vs. time. The mainshock (MS) indicates the sharp increase in rate for the top two distributions. What is a seismic swarm? (McNutt et al., 1995)
Possible Mechanisms • Opening of pathways associated with fluid transport. • Traction on conduit surfaces due to viscous fluid flow. • Sustained crustal deformation and increase in stressing rate (specific to the 2000 Izu Islands’ earthquake swarm).
The 2000 Izu Islands’ Seismic Swarm. • Located 150 km south of Tokyo • Time: June-August 2000. • Recorded more than 7000 M>3 and 5 M>6 events. • Evidence magmatic intrusion (hypothesis).
The Model (Todo et al., 2002) • Seismic activities produced by stress transfers due to crustal deformations initiated by magma intrusions/extrusions. • Very high stress generated for a relatively short period rapidly elevates the earthquake rate episodes. • Model: a vertical dike spread 15km long x 5km wide , continuously propagated for ~2months until the dike opened up by 20m. Real-time monitoring of displacement of ground surface in relation to seismicity. Figure constructed from seismic and GPS (land survey) data. (Todo et al., 2002)
Stress Step vs. Stress Rate Increase • Shear stress rate calculated as a strike-slip fault. • Estimated stress rate near dike = 10 MPa/yr. • Normal stress rate before event = 0.01 MPa/yr. • More than a 1000-fold increase in stressing rate. • Observations consistent with fault friction theory experiments: • Area of seismic activities expanded over time. • The duration of aftershocks of earthquakes of M≥6 were very short. 0.01MPa/yr Figs. c, d - Typical Mainshock-aftershock earthquake. Figs. a, b – Earthquake Swarm. (Toda et al., 2002)
So far we know of two earthquake groups: • Mainshock-aftershock types where the sudden increase in stressing rate triggers temporal burts of seismic activities where aftershocks decay over time. • Earthquake swarm types where the seismic activities increase in proportion to the gradual and sustained increase in stressing rate.
Why are we interested in low-frequency seismic swarms? • Have preceded major volcanic eruptions in the past. Possible predictive tool? • Can provide direct link between surface observations and internal igneous (magmatic) processes. • Link seismicity to deformation; contrast pressure (volumetric) and shear sources.
References Cited • http://kiska.giseis.alaska.edu/dbases/swarmcat/ofr/intro.html • http://sicarius.wr.usgs.gov/animations.html • http://www.vulkaner.no/v/vulkinfo/ordbok/vulktrem-e.html • http://kiska.giseis.alaska.edu/dbases/swarmcat/GVESD.HTML • Benoit, J. P. and S. R. McNutt, Global volcanic earthquake swarm database and preliminary analysis of volcanic earthquake swarm duration, Annali deGeofisca, 39, 221-229, 1996. • Karpin T.L. The relationship between earthquake swarms and magma transport – Kilauea Volcano, Hawaii. Pure and Applied Geophysics 125:971 (1987) • McNutt, S. R. and J. P. Benoit. Generic Earthquake Swarm Model. (extended abs.). Periodico di Mineralogia, 64, 229-230 (1995) • Nishimura, T. et al. Crustal deformation caused by magma migration in the northern Izu Islands, Japan. Geophys. Res. Lett. 28, 3745-3748 (2001) • Toda et al. Evidence from AD 2000 Izu islands earthquake swarm that stressing rate governs seismicity.Nature, 419, p58-61 (2002)