Multi-segment rupture of the 2016 Amatrice-Visso-Norcia seismic sequence (central Italy) constrained by the first high-quality catalog of Early Aftershocks

Improta, Luigi; Latorre, Diana; Margheriti, Lucia; Nardi, Anna; Marchetti, A.; Lombardi, Anna Maria; Castello, Barbara; Villani, Fabio; Ciaccio, Maria Grazia; Mele, F.; Moretti, Milena

doi:10.1038/s41598-019-43393-2

Cited by 87 publications

(127 citation statements)

References 51 publications

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“…This swarm of moderate-size events is part of the 2016-2017 central Italy seismic sequence that affected the central Apennines starting on 24 August 2016 with a M W 6.0 event in the Amatrice area ( Figure 1), and then culminated with the 30 October 2016 M W 6.5 largest event [11]. The geodetic, seismological, and geological studies published so far (e.g., [11][12][13][14][15][16][17][18][19][20]) agree in attributing the bulk of the 2016-2017 central Italy seismic sequence to the progressive rupture of different segments of two main NW-SE striking extensional structures of the central Apennines, the Laga Mts., and Mt. Vettore-Mt.…”

Section: Introductionmentioning

confidence: 91%

Heterogeneous Behavior of the Campotosto Normal Fault (Central Italy) Imaged by InSAR GPS and Strong-Motion Data: Insights from the 18 January 2017 Events

Cheloni¹,

D’Agostino²,

Scognamiglio³

et al. 2019

Remote Sensing

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On 18 January 2017, the 2016–2017 central Italy seismic sequence reached the Campotosto area with four events with magnitude larger than 5 in three hours (major event MW 5.5). To study the slip behavior on the causative fault/faults we followed two different methodologies: (1) we use Interferometric Synthetic Aperture Radar (InSAR) interferograms (Sentinel-1 satellites) and Global Positioning System (GPS) coseismic displacements to constrain the fault geometry and the cumulative slip distribution; (2) we invert near-source strong-motion, high-sampling-rate GPS waveforms, and high-rate GPS-derived static offsets to retrieve the rupture history of the two largest events. The geodetic inversion shows that the earthquake sequence occurred along the southern segment of the SW-dipping Mts. Laga normal fault system with an average slip of about 40 cm and an estimated cumulative geodetic moment of 9.29 × 1017 Nm (equivalent to a MW~6). This latter estimate is larger than the cumulative seismic moment of all the events, with MW > 4 which occurred in the corresponding time interval, suggesting that a fraction (~35%) of the overall deformation imaged by InSAR and GPS may have been released aseismically. Geodetic and seismological data agree with the geological information pointing out the Campotosto fault segment as the causative structure of the main shocks. The position of the hypocenters supports the evidence of an up-dip and northwestward rupture directivity during the major shocks of the sequence for both static and kinematic inferred slip models. The activated two main slip patches are characterized by rise time and peak slip velocity in the ranges 0.7–1.1 s and 2.3–3.2 km/s, respectively, and by ~35–50 cm of slip mainly concentrated in the shallower northern part of causative fault. Our results show that shallow slip (depth < 5 km) is required by the geodetic and seismological observations and that the inferred slip distribution is complementary with respect to the previous April 2009 seismic sequence affecting the southern half of the Campotosto fault. The recent moderate strain-release episodes (multiple M~5–5.5 earthquakes) and the paleoseismological evidence of surface-rupturing events (M~6.5) suggests therefore a heterogeneous behavior of the Campotosto fault.

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Section: Introductionmentioning

confidence: 91%

Heterogeneous Behavior of the Campotosto Normal Fault (Central Italy) Imaged by InSAR GPS and Strong-Motion Data: Insights from the 18 January 2017 Events

Cheloni¹,

D’Agostino²,

Scognamiglio³

et al. 2019

Remote Sensing

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“…A view of the meshes used for the inversions is provided as supporting information ( Figure S1), while parameters used in the GRAV3D algorithm are provided in Table 1. To improve discussion and contribute in validation of the resulting volumes after the inversions, we compare these volumes with catalogs of seismic events from Chiaraluce, Di Stefano, et al (2017) and from Improta et al (2019). In the local volume, the first catalog counts over 18,700 events with M ≥ 0.1 registered between 24 August 2016 and 29 November 2016 and located between depths of 21 and − 1.9 km.…”

Section: Resultsmentioning

confidence: 99%

“…It is interesting to compare the geometries and densities obtained after the inversion, with the spatial distribution of seismic events within the local volume (Figures 4(b), 4(c), and 5). In particular, we use events with seismic magnitude M ≥ 3 from the catalog of Chiaraluce, Di Stefano, et al (2017) and the relocated aftershocks catalog of Improta et al (2019). We note that the large majority of data from both catalogs locates in the intermediate volume (i.e., carbonates and evaporites) with deeper events located in the upper basement.…”

Section: Inversion Using the Three-volume Reference Modelmentioning

confidence: 99%

“…The 2016-2017 seismic sequence that occurred in the area counted several tens of thousands of events with M ≤ 6.5 between depths of 0 and 15 km (Chiaraluce, Di Stefano, et al, 2017;Improta et al, 2019) and two relevant mainshocks on 24 August 2016 with M w 6.0 and on 30 October 2016 with M w 6.5 (Figure 1(a)). Similar to northern areas along the active extension in the Apenninic belt (Barchi, 2002;Latorre et al, 2016;Mirabella et al, 2008), the majority of the events in the 2016-2017 sequence was located within the sedimentary units, above the basement sensu lato (e.g., Mancinelli et al, 2019;Porreca et al, 2018) strengthening the hypothesis that the basement, or the lithological change at the base of the sedimentary units, could exert a significant role in controlling the depth distribution of seismicity (Barchi, 2002;Mirabella et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

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Three dimensional Gravity Local Inversion Across the Area Struck by the 2016–2017 Seismic Events in Central Italy

et al. 2020

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In this work, the crustal volume struck by the 2016–2017 seismic sequence in Central and Northern Apennines is investigated using constrained 3‐D inversion of the gravity anomalies. In order to focus on the area comprising the two mainshocks of the sequence, we perform a regional field removal on the data as a preprocessing step. This residual data set is then inverted into a 3‐D density contrast model. We perform a series of inversions to test different geological scenarios and parameters, with increasing complexity in the reference geometries. We first test a model comprising turbidites, carbonates and evaporites, and basement and then introduce a low‐density layer at the top of the basement. The geometries are obtained in agreement with the available geological and geophysical information in the area. We found that the density distribution with depth is compatible with previous models. Moreover, results support the hypothesis based on borehole evidence of a low‐density upper basement across the entire area, possibly consisting of low‐grade metamorphic rocks (phyllites). Finally, we compare our modeling results to the spatial distribution at depth of major seismic events between August and November 2016. These events appear to be concentrated within the denser units at both shallow and deep locations, while the deeper events often occur in a region of major density contrast corresponding to the top of the basement.

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“…confirms the sawtooth profile as a distinctive feature of foreshock activity. 1 Visso foreshock belong to this situation 31,34 . In this case a fraction of the stress is redistributed within the "no-aftershock" red zone but the remaining stress is concentrated within the green zone, leading to normal aftershock activity.…”

mentioning

confidence: 97%

Recognizing the waveform of a foreshock

Lippiello¹,

Petrillo²,

Godano³

2020

Preprint

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The 2011 Mw9.1 Tohoku, Japan, earthquake is the paradigmatic example of an earthquake anticipated by a significant foreshock activity, with a Mw7.3 earthquake occurred two days before, within about 10 km 1. Recent results 2 show that statistically relevant changes can be found in the magnitude distribution after the Mw7.3 foreshock but the discrimination between normal and foreshock activity still remains a scientific challenge 3. Here we show that the envelope of the ground velocity recorded after the Mw7.3 foreshock presents an atypical sawtooth profile very different from the one observed after other earthquakes 4. We interpret this profile as the consequence of the locked state of the mainshock fault which reduces the possibility of the foreshock to trigger its own aftershocks. We find a similar sawtooth profile after other Mw6+ foreshocks followed within 10 days by a larger earthquake, as in the case of the 2014 Mw8.1 Iquique, Chile, sequence. This observation allows us to define a level of concern, simply extracted from the first 45 minutes of the recording waveform, associated to the occurrence of a larger earthquake. A test of the method for 47 Mw6+ worldwide earthquakes gives precise warning in time and space after all the 10 earthquakes followed by a larger one with only 2 false alerts.

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Multi-segment rupture of the 2016 Amatrice-Visso-Norcia seismic sequence (central Italy) constrained by the first high-quality catalog of Early Aftershocks

Cited by 87 publications

References 51 publications

Heterogeneous Behavior of the Campotosto Normal Fault (Central Italy) Imaged by InSAR GPS and Strong-Motion Data: Insights from the 18 January 2017 Events

Heterogeneous Behavior of the Campotosto Normal Fault (Central Italy) Imaged by InSAR GPS and Strong-Motion Data: Insights from the 18 January 2017 Events

Three dimensional Gravity Local Inversion Across the Area Struck by the 2016–2017 Seismic Events in Central Italy

Recognizing the waveform of a foreshock

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