New insights on volcanic and tectonic structures of the southern Tyrrhenian (Italy) from marine and land seismic data
Language
English
Obiettivo Specifico
1.4. TTC - Sorveglianza sismologica delle aree vulcaniche attive
3.3. Geodinamica e struttura dell'interno della Terra
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Issue/vol(year)
/14 (2013)
ISSN
1525-2027
Electronic ISSN
1525-2027
Publisher
American Geophysical Union
Pages (printed)
3703–3719
Date Issued
2013
Subjects
Abstract
We present results from the first crustal seismic tomography for the southern Tyrrhenian area, which includes ocean bottom seismometer (OBS) data and a bathymetry correction. This area comprises Mt. Etna, the Aeolian Islands, and many volcanic seamounts, including the Marsili Seamount. The seismicity distribution in the area depends on the complex interaction between tectonics and volcanism. The 3-D
velocity model presented in this study is obtained by the inversion of P wave arrival times from crustal earthquakes. We integrate travel time data recorded by an OBS network (Tyrrhenian Deep Sea Experiment), the SN-1 seafloor observatory, and the land network. Our model shows a high correlation
between the P wave anomaly distribution and seismic and volcanic structures. Two main low-velocity anomalies underlie the central Aeolian Islands and Mt. Etna. The two volumes, which are related to the
well-known active volcanism, are separated and located at different depths. This finding, in agreement with structural, petrography, and GPS data from literature, confirms the independence of the two systems.
The strongest negative anomaly is found below Mt. Etna at the base of the crust, and we associate it with the deep feeding system of the volcano. We infer that most of the seismicity is generated in brittle rock
volumes that are affected by the action of hot fluids under high pressure due to the active volcanism in the area. Lateral changes of velocity are related to a transition from the western to the central Aeolian Islands and to the passage from continental crust to the Tyrrhenian oceanic uppermost mantle.
velocity model presented in this study is obtained by the inversion of P wave arrival times from crustal earthquakes. We integrate travel time data recorded by an OBS network (Tyrrhenian Deep Sea Experiment), the SN-1 seafloor observatory, and the land network. Our model shows a high correlation
between the P wave anomaly distribution and seismic and volcanic structures. Two main low-velocity anomalies underlie the central Aeolian Islands and Mt. Etna. The two volumes, which are related to the
well-known active volcanism, are separated and located at different depths. This finding, in agreement with structural, petrography, and GPS data from literature, confirms the independence of the two systems.
The strongest negative anomaly is found below Mt. Etna at the base of the crust, and we associate it with the deep feeding system of the volcano. We infer that most of the seismicity is generated in brittle rock
volumes that are affected by the action of hot fluids under high pressure due to the active volcanism in the area. Lateral changes of velocity are related to a transition from the western to the central Aeolian Islands and to the passage from continental crust to the Tyrrhenian oceanic uppermost mantle.
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it/CSI/.].
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Ionian Basin, Geophys. J. Int., 144, 49–64.
Chiarabba, C., L. Jovane, and R. Di Stefano (2005), A new
view to the Italian seismicity using 20 years of instrumental
recordings, Tectonophysics, 395, 251–268, doi:10.1016/
j.tecto.2004.09.013.
Dahm, T., and T. Becker (1998), On the elastic and viscous
properties of media containing strongly interacting in-plane
cracks, PAGEOPH, 151, 1–16.
Dahm, T., M. Thorwart, E. R. Flueh, T. Braun, R. Herber, P.
Favali, L. Beranzoli, G. D’Anna, F. Frugoni, and G. Smriglio
(2002), Ocean bottom seismometers deployed in Tyrrhenian
Sea, Eos Trans. AGU, 83(29), 309–315.
De Astis, G., G. Ventura, and G. Vilardo (2003), Geodynamic
significance of the Aeolian volcanism (southern Tyrrhenian
Sea, Italy) in light of structural, seismological, and geochemical
data, Tectonics, 22(4), 1040, doi:10.1029/2003TC001506.
De Luca, G., L. Filippi, D. Caccamo, G. Neri, and R. Scarpa
(1997), Crustal structure and seismicity of southern Tyrrhenian
basin, Phys. Earth Planet. Inter., 103, 117–133.
Di Stefano, R., C. Chiarabba, F. Lucente, and A. Amato
(1999), Crustal and uppermost mantle structure in Italy from
the inversion of P-wave arrival times: Geodynamic implications,
Geophys. J. Int., 139, 483–498, doi:10.1046/j.1365-
246x.1999.00952.x.
Di Stefano, R., I. Bianchi, M. G. Ciaccio, G. Carrara, and E.
Kissling (2011), Three-dimensional Moho topography in
Italy : New constraints from receiver functions and controlled
source seismology, Geochem. Geophys. Geosyst., 12,
Q09006, doi:10.1029/2011GC003649.
Doglioni, C. (1991), A proposal kinematic modeling for
W-dipping subductions—Possible applications to the
Tyrrhenian-Apennine systems, Terra Nova, 3, 423–434.
Doglioni, C., F. Innocenti, and G. Mariotti (2001), Why Mt.
Etna?, Terra Nova, 13, 25–31.
Falsaperla, S., G. Lanzafame, V. Longo, and S. Spampinato
(1999), Regional stress field in the area of Stromboli (Italy) :
Insights into structural data and crustal tectonic earthquakes,
J. Volcanol. Geotherm. Res., 88, 147–166.
Favali, P., et al. (2006), A fleet of multiparameter observatories
for geophysical and environmental monitoring at seafloor,
Ann. Geophys., 49(2/3), 659–680.
Frepoli, A., and A. Amato (2000), Spatial variation in stresses
in peninsular Italy and Sicily from background seismicity,
Tectonophysics, 317, 109–124.
GLOBE Task Team et al. (1999), The Global Land One-
Kilometer Base Elevation (GLOBE) Digital Elevation
Model, Version 1.0, http://www.ngdc.noaa.gov/mgg/topo/
globe.html and CD-ROMs, Natl. Oceanic and Atmos.
Admin., Natl. Geophys. Data Cent., Boulder, Colo.
Grad, M., T. Tiira, and ESC Working Group (2009), The
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