Present‐Day Surface Deformation of Sicily Derived From Sentinel‐1 InSAR Time‐Series

The Quaternary geodynamics of the Central Mediterranean region is controlled by the migration of narrow orogenic belts within the slow Nubia‐Eurasia plate convergence. As testified by the occurrence of major volcanic and seismic events, the Eastern Sicilian Margin is presently one of the most active...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2022-03, Vol.127 (3), p.n/a
Main Authors: Henriquet, Maxime, Peyret, Michel, Dominguez, Stéphane, Barreca, Giovanni, Monaco, Carmelo, Mazzotti, Stéphane
Format: Article
Language:English
Subjects:
Anthropogenic factors
Belts
Convergence
Deformation
Earthquakes
Geodynamics
Geophysics
Global navigation satellite system
GNSS
Gravity
Image acquisition
Landslides
Line of sight
Mathematical analysis
mean surface velocity field
Orogeny
Plate convergence
Plates (tectonics)
PS‐InSAR
Quaternary
Satellite imagery
Satellites
Sciences of the Universe
Seismic activity
Seismic zones
Sentinel‐1
Sicily
Spaceborne remote sensing
Subsidence
Surface velocity
Synthetic aperture radar interferometry
Tectonics
Tectonophysics
Uplift
Velocity
Velocity distribution
Vertical velocities
Volcanic activity
Volcanoes
Wavelength
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Summary:The Quaternary geodynamics of the Central Mediterranean region is controlled by the migration of narrow orogenic belts within the slow Nubia‐Eurasia plate convergence. As testified by the occurrence of major volcanic and seismic events, the Eastern Sicilian Margin is presently one of the most active regions. Using a Permanent‐Scatterer approach, we process Sentinel‐1 satellite images acquired from 2015 to 2020 to provide an island‐wide quantification of surface displacements at a high spatiotemporal resolution. We then convert the calculated mean surface velocities along the ascending and descending satellite line of sight into the ITRF2014 reference frame by using GNSS velocity data derived from regional stations. The resulting pseudo‐3D velocity field mainly highlights a general uplift of about 1.5 ± 0.5 mm/yr of the Nebrodi‐Peloritani range and its differential motion with respect to mainland Sicily along the Cefalù‐Etna seismic zone. Permanent/Persistent‐Scatterer (PS) vertical velocities in the Eastern Hyblean region reveal a long wavelength eastward downbending of the margin, including the inferred epicentral area of the 1693 Noto earthquake. Compared to Quaternary coastal uplift rates, these results confirm the relative low activity of Western Sicily, a potential slow uplift of South‐Central Sicily and a significant discrepancy along the Eastern Hyblean margin were PS‐derived vertical velocities that appear 2–3 mm/yr lower than the Quaternary rates. Over the 2015–2020 timespan, transient processes are also captured, notably on Mount Etna, showing both magmatic pressurization uplift and collapse of the eastern flank, but also all over Sicily where numerous gravitational mass movements and anthropogenic ground subsidence are detected. Plain Language Summary The recent geodynamics of Central Mediterranean is controlled by the migration of narrow orogenic belts within the slow Nubia‐Eurasia plate convergence. As testified by major volcanic and seismic events, the Eastern Sicilian Margin is a region of strong tectonic activity. Using a Permanent‐Scatterer approach, we process Sentinel‐1 data to provide an island‐wide quantification of surface displacements from 2015 to 2020. We convert the calculated mean surface velocities along the satellite line of sight into the ITRF2014 reference frame using GNSS data. The resulting velocity fields highlight a general uplift of the Nebrodi‐Peloritani range and its differential motion relative to mainland Sicily alon
ISSN:2169-9313
2169-9356
DOI:10.1029/2021JB023071