New insights into active tectonics and seismogenic potential of the Italian Southern Alps from vertical geodetic velocities

Anderlini, Letizia; Serpelloni, Enrico; Tolomei, Cristiano; Martini, P. M. De; Pezzo, Giuseppe; Gualandi, Adriano; Spada, Giorgio

doi:10.5194/se-11-1681-2020

Cited by 32 publications

(58 citation statements)

References 93 publications

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“…At the time scale of a few years, Adria plate kinematics can be considered as a stationary process (Anderlini et al, 2020;D'agostino et al, 2005Devoti et al, 2008). Therefore, we consider the linear velocity model as the most suitable description of the tectonic displacement at the CGPS points; however, the offshore platforms may be affected by local ground deformation due to the exploitation of gas fields, and CGPS velocities may thus vary with time.…”

Section: 1029/2020tc006425mentioning

confidence: 99%

“…In order to estimate the current slip rate of the major identified faults, we simulated the surface deformation associated with an uniform slip over the regional thrust detachment, by using a simple 2-D modeling approach, largely applied to different tectonic domains worldwide (e.g., Anderlini et al, 2020;Fialko, 2006;Ponraj et al, 2019;Vergne et al, 2001). The computation of a 2-D profile model allowed us to simulated an infinite wide (perpendicular to the profile) regional thrust detachment, avoiding lateral deformation effects ( Figure 6).…”

Section: Modeling Of Fault-related Deformationmentioning

confidence: 99%

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Active Fold‐Thrust Belt to Foreland Transition in Northern Adria, Italy, Tracked by Seismic Reflection Profiles and GPS Offshore Data

et al. 2020

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The Adria microplate is the foreland of the oppositely verging Apennines and Alps or Dinarides fold-thrust belts associated to the related subduction zones. Along its western margin, the Adria plate hosts the active Northern Apennines accretionary prism, which is buried under the Adriatic Sea and the Po Plain. The interpretation of seismic reflection profiles and borehole data allowed us to define the geometry of the transition from the Apennines fold-thrust belt to its undeformed foreland. Moreover, continuous GPS (CGPS) data from offshore hydrocarbon platforms anchored to the seabed of the northern Adriatic plate allow to measure present-day kinematics. Although the CGPS signals are affected by non-tectonic components associated with hydrocarbon extraction, the integration of geodetic analysis, subsurface geological reconstructions, and analytical modeling allowed us to constrain the ongoing tectonic activity. Shortening is currently accommodated by aseismic slip along the basal detachment, likely accumulating elastic energy along the frontal ramp that may eventually seismically slip. Our multidisciplinary study suggests that the study area may not be sheltered from relevant seismic sequences similar to the Mw 6 Emilia 2012 events and that the occurrence of potential seismogenic sources in the area should be carefully evaluated. Similar studies may be useful to constrain the present-day activity in other marine areas and to identify potential and hitherto unrecognized seismogenic sources along the entire Apennines belt and other accretionary prisms worldwide.

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Section: 1029/2020tc006425mentioning

confidence: 99%

Section: Modeling Of Fault-related Deformationmentioning

confidence: 99%

Active Fold‐Thrust Belt to Foreland Transition in Northern Adria, Italy, Tracked by Seismic Reflection Profiles and GPS Offshore Data

et al. 2020

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“…The estimated vertical slip rate of the Euganean Hills is at least 0.4 mm/y once compared with Mt. Netto (Livio et al, 2020) and Montello (Anderlini et al, 2020). Even though during glacial stages, the alluvial plain grew remarkably faster than the Euganean Hills (3-7.5 times faster during the LGM), the uplift of the latter could have filled the gap during interglacial times, when the alluvial sedimentation was lower.…”

Section: Deformation Pattern and Geomorphological Evolution Of The Eumentioning

confidence: 88%

“…If the slip rate of the frontal part of the Euganean Hills was at least 0.4 mm/y, as estimated by Livio et al (2020) for Mt. Netto near Brescia, and by Anderlini et al (2020) for the Montello thrust, then ∼2^10 6 years could have been sufficient to deform and expose the Scaglia Rossa after the formation of the gouge layer.…”

Section: Pulverizationmentioning

confidence: 99%

Paleo-Seismicity in the Euganean Hills Province (Northeast Italy): Constraints From Geomechanical and Geophysical Tests in the Schio-Vicenza Fault Area

et al. 2020

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Gouges and cataclasites within exhumed fault zones are valuable indicators of past seismic events. Gouge layers, 40- to 100-cm-thick and decameters long, have been found within uplifted Cretaceous limestones in the Euganean Hills (SW of Padova, NE Italy), Cenozoic subvolcanic chambers intruded within a Meso-Cenozoic sequence. The main tectonic lineament in the area is the Schio-Vicenza Fault that bounds the Euganean Hills to the East. Micropaleontological analyses reveal that the gouges derive from the fragmentation and pulverization of the adjacent pristine carbonatic rocks. Stress tests on specimens from bedrock associated with gouges yielded a minimum dissipated strain energy of 0.3–0.5 MJ/m3 to shatter them. Henceforth, additional strain energy was necessary to pulverize these rocks within the gouge zones. Global navigation satellite system observations show that the present deformation pattern in this region of Italy is a few tens of nanostrain (10–30 1/y), not enough to generate such gouge layers. Therefore, the seismicity of the Euganean Hills (currently M ≤5) must be reconsidered in the light of the Schio-Vicenza Fault past activity. The gouges may imply that the Schio-Vicenza Fault had a more intense activity in the past, or this area was affected by remote events or tectonic structures. This article provides new clues on the evolution of the tectonic and morphological setting of the area, with relevant consequences on seismic risk assessment of the nearby urbanized area, including the cities of Padova and Vicenza.

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“…Historical seismicity (e.g. Galadini et al, 2005) and clustering of (micro-)seismic hypocenters (Romano et al, 2019;Anderlini et al, 2020;Jozi Najafabadi et al, 2020) along these fault systems and morphological evidence of fault surface rupture (Moratto et al, 280 2019;Romano et al, 2019) indicate that this younger phase of shortening is still active.…”

Section: Permian To Jurassic Paleogeography 145mentioning

confidence: 99%

Comment on se-2021-19

Zampieri¹

2021

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Neogene indentation of the Adriatic plate into Europe led to major modifications of the Alpine orogenic structures and style of deformation in the Eastern Alps. Especially, the offset of the Periadriatic Fault by the Northern Giudicarie Fault marks the initiation of strike-slip faulting and lateral extrusion of the Eastern Alps. Questions remain on the exact role of this fault zone in changes of the Alpine orogen at depth. This necessitates quantitative analysis of the 5 shortening, kinematics and depth of decoupling underneath the Northern Giudicarie Fault and associated fold-and thrust belt in the Southern Alps. Tectonic balancing of a network of seven cross sections through the Giudicarie Belt parallel to the local shortening direction reveals that it comprises two kinematic domains with different amounts and partly overlapping ages of shortening. These two domains are delimitated by the NW-SE oriented strike-slip Trento-Cles -Schio-Vicenza fault system, cross-cutting the Southern Alpine orogenic front in the south and merging with 10 the Northern Giudicarie Fault in the north. The SW kinematic domain (Val Trompia sector) accommodated at least ~18 km of Late Oligocene to Early Miocene shortening. Since the Middle Miocene, the SW kinematic domain experienced a minimum of ~12-22 km shortening, whereas the NE kinematic domain underwent at least ~25-35 km shortening. Together, these domains contributed to an estimated ~53-75 km of sinistral strike-slip motion along the Northern Giudicarie Fault, implying that (most of) the offset of the Periadriatic Fault is due to Late Oligocene to 15 Neogene indentation of the Adriatic plate into the Eastern Alps. Moreover, the faults linking the Giudicarie Belt with the Northern Giudicarie Fault reach ~15-20 km depth, indicating a thick-skinned tectonic style of deformation. These fault detachments may also connect at depth with a lower crustal Adriatic wedge that protruded north of the Periadriatic Fault and was responsible for N-S shortening and eastward escape of deeply exhumed units in the Tauern Window. Finally, the east-west lateral variation of shortening indicates internal deformation and lateral variation in 20 strength of the Adriatic indenter, related to Permian -Mesozoic tectonic structures and paleogeographic domains. 25

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New insights into active tectonics and seismogenic potential of the Italian Southern Alps from vertical geodetic velocities

Cited by 32 publications

References 93 publications

Active Fold‐Thrust Belt to Foreland Transition in Northern Adria, Italy, Tracked by Seismic Reflection Profiles and GPS Offshore Data

Active Fold‐Thrust Belt to Foreland Transition in Northern Adria, Italy, Tracked by Seismic Reflection Profiles and GPS Offshore Data

Paleo-Seismicity in the Euganean Hills Province (Northeast Italy): Constraints From Geomechanical and Geophysical Tests in the Schio-Vicenza Fault Area

Comment on se-2021-19

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