68 research outputs found
Faults geometry and the role of fluids in the 2016-2017 Central Italy seismic sequence
The 2016–2017 Central Italy seismic sequence ruptured overlapping normal faults of the Apennines mountain chain, in nine earthquakes with magnitude Mw > 5 within a few months. Here we investigate the structure of the fault system using an extensive aftershock data set, from joint permanent and temporary seismic networks, and 3‐D Vp and Vp/Vs velocity models. We show that mainshocks nucleated on gently west dipping planes that we interpret as inverted steep ramps inherited from the late Pliocene compression. The two large shocks, the 24 August, Mw = 6.0 Amatrice and the 30 October, Mw = 6.5 Norcia occurred on distinct faults reactivated by high pore pressure at the footwall, as indicated by positive Vp/Vs anomalies. The lateral extent of the overpressurized volume includes the fault patch of the Norcia earthquake. The irregular geometry of normal faults together with the reactivated ramps leads to the kinematic complexity observed during the coseismic ruptures and the spatial distribution of aftershocks
Evidence for surface rupture associated with the Mw 6.3 L’Aquila earthquake sequence of April 2009 (central Italy)
An earthquake of Mw = 6.3 struck L Aquila town (central Italy) on 6 April 2009 rupturing an ~18-km-long SW-dipping normal fault. The aftershock area extended for a length of more than 35 km and included major aftershocks on 7 and 9 April and thousands of minor events. Surface faulting occurred along the SW-dipping Paganica fault with a continuous extent of ~2.5 km. Ruptures consist of open cracks and vertical dislocations or warps (0.1m maximum throw) with an orientation of N130°–140°. Small triggered slip and shaking effects also took place along nearby synthetic and antithetic normal faults. The observed limited extent and small surface displacement of the Paganica ruptures with respect to the height of the fault scarps and vertical throws of palaeo-earthquakes along faults in the area put the faulting associated with the L' Aquila earthquake in perspective with respect to the maximum expected magnitude and the regional seismic hazard.Published43-513.2. Tettonica attivaJCR Journalreserve
Evidence for surface rupture associated with the Mw 6.3 L’Aquila earthquake sequence of April 2009 (central Italy)
An earthquake of Mw=6.3 struck L’Aquila town (central Italy) on April 6, 2009 rupturing an
approximately 18 km long SW-dipping normal fault. The aftershock area extended for a length of more than 35 km and included major aftershocks on April 7 and 9, and thousands of minor events.
Surface faulting occurred along the SW-dipping Paganica fault with a continuous extent of ~2.5 km.
Ruptures consist of open cracks and vertical dislocations or warps (0.1 maximum throw) with an orientation of N130°-N140°. Small triggered slip and shaking effects also took place along nearby synthetic and antithetic normal faults. The observed limited extent, and small surface displacement, of the Paganica ruptures with respect to the height of the fault scarps and vertical throws of paleoearthquakes along faults in the area, puts the faulting associated with the L’Aquila earthquake in perspective with respect to the maximum expected magnitude, and the regional seismic hazard
A photographic dataset of the coseismic geological effects induced on the environment by the 2012 Emilia (Northern Italy) earthquake sequence
We present a collection of pictures of the coseismic secondary geological effects produced on the
environment by the 2012 Emilia seismic sequence in northern Italy. The May-June 2012 sequence struck a
broad area located in the Po Plain region, causing 26 deaths and hundreds of injured, 15.000 homeless,
severe damage of historical centres and industrial areas, and an estimated economic toll of ~2 billion of
euros. The sequence included two mainshocks (Figure 1): the first one, with ML 5.9, occurred on May 20
between Finale Emilia, S. Felice sul Panaro and S. Martino Spino; the second one, with ML 5.8, occurred 12
km southwest of the previous mainshock on May 29. Both the mainshocks occurred on about E-W trending,
S dipping blind thrust faults; the whole aftershocks area extends in an E-W direction for more than 50 km
and includes five ML≥5.0 events and more than 1800 ML>1.5 events. Ground cracks and liquefactions were
certainly the most relevant coseismic geological effects observed during the Emilia sequence. In particular,
extensive liquefaction was observed over an area of ~1200 km2 following the May 20 and May 29 events.
We collected all the coseismic geological evidence through field survey, helicopter and powered hang-glider
trike survey, and reports from local people directly checked in the field. On the basis of their morphologic
and structural characteristics the 1362 effects surveyed were grouped into three main categories: a)
liquefactions related to overpressure of aquifers, occurring through several aligned vents forming coalescent
flat cones (485 effects); b) liquefactions with huge amounts of liquefied sand and fine sand ejected from
fractures tens of meters long (768); c) extensional fractures with small vertical throws, apparently organized
in an en-echelon pattern, with no effects of liquefaction (109). The photographic dataset consists of 99
pictures of coseismic geological effects observed in 17 localities concentrated in the epicentral area. The
pictures are sorted and presented by locality of observation; each photo reports several information such as
the name of the site, the geographical coordinates and the type of effect observed. Figure 1 shows a map of
the pictures sites along with the location of the two mainshocks; Figure 2 shows a detail of the distribution of
the liquefactions in the area of S. Carlo. The complete description of the coseismic geological effects
induced by the Emilia sequence, their relation with the aftershock area, the InSAR deformation area and the
I>6 EMS felt area, along with the description of the technologies used for data sourcing and processing are
shown in Emergeo Working Group [2012a and 2012b].Published1-703.2. Tettonica attivaN/A or not JCRope
Evidence for surface rupture associated with the Mw 6.3 L’Aquila earthquake sequence of April 2009 (central Italy)
An earthquake of Mw = 6.3 struck L Aquila town (central Italy) on 6 April 2009 rupturing an ~18-km-long SW-dipping normal fault. The aftershock area extended for a length of more than 35 km and included major aftershocks on 7 and 9 April and thousands of minor events. Surface faulting occurred along the SW-dipping Paganica fault with a continuous extent of ~2.5 km. Ruptures consist of open cracks and vertical dislocations or warps (0.1m maximum throw) with an orientation of N130°–140°. Small triggered slip and shaking effects also took place along nearby synthetic and antithetic normal faults. The observed limited extent and small surface displacement of the Paganica ruptures with respect to the height of the fault scarps and vertical throws of palaeo-earthquakes along faults in the area put the faulting associated with the L' Aquila earthquake in perspective with respect to the maximum expected magnitude and the regional seismic hazard
Geodetic model of the 2016 Central Italy earthquake sequence inferred from InSAR and GPS data
We investigate a large geodetic data set of interferometric synthetic aperture radar (InSAR)and GPS measurements to determine the source parameters for the three main shocks of the 2016Central Italy earthquake sequence on 24 August and 26 and 30 October (Mw6.1, 5.9, and 6.5,respectively). Our preferred model is consistent with the activation of four main coseismic asperitiesbelonging to the SW dipping normal fault system associated with the Mount Gorzano-Mount Vettore-Mount Bove alignment. Additional slip, equivalent to aMw~ 6.1–6.2 earthquake, on a secondary (1) NEdipping antithetic fault and/or (2) on a WNW dipping low-angle fault in the hanging wall of the mainsystem is required to better reproduce the complex deformation pattern associated with the greatestseismic event (theMw6.5 earthquake). The recognition of ancillary faults involved in the sequencesuggests a complex interaction in the activated crustal volume between the main normal faults and thesecondary structures and a partitioning of strain releas
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