Royal Dutch Meteorological Institute; Ministery Of Infrastructure And The Environment

Publications, presentations and other activities
Imaging Torfajökull's magmatic plumbing system with seismic interferometry and phase velocity surface wave tomography
2019
by J.E. Martins (Delft University of Technology), E.N. Ruigrok (KNMI), D. Draganov (Delft University of Technology), A. Hooper (University of Leeds), R.F. Hanssen (Delft University of Technology)R.S. White (University of Cambridge)H. Soosalu (University of Cambridge)

Torfajökull volcano, Iceland, has not erupted since 1477. However, intense geothermal activity, deformation, and seismicity suggest a long-lasting magmatic system. In this paper, we use ambient noise tomography to image the magmatic system beneath Torfajökull volcano. One hundred days of ambient noise data from 23 broadband seismometers show the consistent presence of double-frequency microseism noise with significant power between ∼ 0.1 and 0.5 Hz. Beamforming results indicate microseism noise with persistent higher energy propagating from west and SE directions and apparent velocities below 3 km/s. We use ambient noise seismic interferometry to retrieve Rayleigh waves, and we introduce a method to estimate the reliability of the retrieved surface waves. We find stable estimation of surface wave phase velocities between 0.16 and 0.38 Hz. Azimuthal velocity variations show a trend of higher velocities in the NE/SW direction, the strike of the rift zone intersecting Torfajökull, and orientation of erupted lavas on a NE-SW fissure swarm. Tomographic results indicate low-velocity anomalies beneath the volcano caldera (between − 5% and − 10%) and even lower velocity variations in the southeast and southwest study area (below − 10%), outside the volcano caldera. Low anomalies may indicate the existence of hot material, more prominent outside the caldera outskirts. High-velocity variations (between 5% and 10%) outline the volcano caldera between 4- and 5-km depth and more pronounced velocities (between 10% and 15%) up to 5-km depth in the north of the volcano caldera. We interpret the former as possible caldera collapse structure and the latest as solidified intrusive magma from the old preferred magma paths.

Bibliographic data
Martins, J.E., E.N. Ruigrok, D. Draganov, A. Hooper, R.F. Hanssen, R.S. White and H. Soosalu, Imaging Torfajökull's magmatic plumbing system with seismic interferometry and phase velocity surface wave tomography
J. Geophys. Res., 2019, 124, 2920-2940, doi:10.1029/2018JB016002.
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