ALBERT

Description: In questi ultimi anni molti Enti o Università italiane e straniere impegnate in studi geofisici a carattere geodinamico e geodetico, hanno sentito la necessità di realizzare reti GPS in monitoraggio continuo capaci di raggiungere le migliori precisioni possibili ottenibili e al contempo di poter disporre di dati inquadrati in un solo sistema di riferimento. Infatti i dati GPS acquisiti in continuo su reti realizzate con procedure automatizzate di acquisizione, trasmissione e analisi dei dati, rappresentano un potente mezzo per studiare le deformazioni del suolo di origine tettonica e vulcanica, consentendo avanzamenti significativi nella ricerca geofisica e geodetica e per scopi di monitoraggio orientati per applicazioni di Protezione Civile. Con questi obiettivi sono state realizzate le stazioni GPS di Roma (INGR), Villavallelonga (VVLO), Roseto degli Abruzzi (RSTO), Gibilmanna (GBLM), Preturo (INGP) e Monte Argentario (MAOO), distribuite nelle aree italiane di principale interesse geodinamico e sismologico. Queste sono state collocate in particolare dove andava colmato un gap sulla distribuzione di stazioni permanenti già esistenti afferenti alla rete GPS dell’Agenzia Spaziale Italiana. Le stazioni, realizzate secondo criteri che soddisfano la ricerca geofisica, sono costituite da ricevitori GPS geodetici a doppia frequenza le cui antenne sono state collocate su pilastrini in cemento armato prevalentemente fondati su affioramenti rocciosi. In questa pubblicazione viene descritto lo stato attuale della rete, la struttura dei monumenti geodetici, la strumentazione utilizzata, le modalità di acquisizione e trasmissione dei dati, la loro analisi e archiviazione. Viene anche mostrato un confronto sulla qualità dei dati prodotti dalle stazioni INGV rispetto alle stazioni di Matera (MATE) e Cagliari (CAGL), afferenti alla rete internazionale dell’International Godynamic Service.

Description: Published

Description: 1-50

Description: 1.9. TTC - Rete GPS nazionale

Description: open

Description: On November 24, 2004, Northern Italy was struck by a Ml=5.2 earthquake located near the Garda Lake. A few smaller events followed the main shock. The felt area was very large, ranging from Venice to Milan, and from Ljubljana (Slovenia) to Pisa. Significant damage occurred in the epicentral area, which is approximately the same of the October 30, 1901 earthquake. The day after the quake, reconnaissance teams performed a macroseismic survey of the affected area in order to define the damage scenario. Damage was mostly concentrated in the area west of Lake Garda, between the town of Salò and the Valsabbia valley. Damage to old masonry buildings consisted in partial collapses, falling of chimneys and roof tiles and large cracks in walls. Some churches and towers were also damaged. There was almost no damage to reinforced concrete (RC) structures.

Description: Published

Description: 44-59

Description: 5.1. TTC - Banche dati e metodi macrosismici

Description: N/A or not JCR

Description: restricted

Description: In May-July 2012, the Emilia Romagna (Northern Italy) was struck by a significant seismic sequence, characterized by two moderate-magnitude earthquakes: a Ml 5.9 event on May 20th, 2012 at 02:03:53 UTC, and a Ml 5.8 event on May 29th, at 07:00:03 UTC, about 12 km to the west of the first one. The earthquake sequence produced a total number of 20 casualties and severe and diffuse damages, mainly on historical buildings and commercial sheds.

Description: Published

Description: 773-779

Description: 1.9. Rete GPS nazionale

Description: JCR Journal

Description: open

Description: The GPS results are of utmost relevance for the study of the complex plate boundary geodynamics. The lithosphere strain partitioning is part of the seismic cycle. We present the first GPS kinematic pattern obtained during the interseismic phase by a dense episodic GPS network, the Southern Apennine Geodetic Network - SAGNet (Sepe et al., 2009), in the time span 2002-2013. This network is located across the transition zone between central and southern Apennine, including Meta-Mainarde-Venafro and AltoMolise-Sannio-Matese mounts. This region is characterized by seismogenic fault systems responsible, in the past, for several destructive earthquakes of intensity I ≥ IX MCS and, in more recent years, characterised mainly by some moderate magnitude seismic sequences (max magnitude Mw 5.0, December 29 2013) and single small events (Ml 〈 2.5).SAGNet GPS data were processed by BERNESE sw v.5.0 and the resulting velocities were least-squares combined with the permanent stations velocity field and with the velocity solution of Giuliani et al. 2009. The combined GPS velocity field, shows a perpendicular maximum extension with respect to the Apennine chain of about 2.0 mm/y.The Matese area was hit on December 29, 2013 by a Mw=5.0 (Convertito et al., 2016) earthquake. It was followed by an intense seismic activity until the beginning of February 2014. After the mainshock a GPS survey was carried out on the SAGnet stations. We collected data from 2013, 30 December to 2014, 4 April. The time series of 17 stations are affect by an offsets on the linear drift. The map of horizontal coseismic displacements (Figure 3) shows a sub-radial displacement shape with respect to the epicentre. Larger displacements are observed in correspondence of NE portion of the Matese massif. Considering the Matese Lake Fault as the probable source of the mainshock (dip 65°, strike 116, rake 270 – MLF, Ferranti et al, 2015), we found that the Okada modelling does not fit the observed displacements and only a small fraction of displacements are resolved with a simple slip.Figure 4 resembles the results of previous studies compared with our GPS analysis. We considered seismological analyses, tomographic models, degassing of CO2 data and conceptual model of processes recognized in South Apennine (L. Bisio, et al., 2004; Chiarabba and Chiodini, 2013; Improta et al., 2014; Ventura et al., 2007, R. Di Stefano and M.G. Ciaccio, 2014; Ferranti et al., 2015; Convertito et al., 2016;). The GPS results indicate that the relative motion between Eurasia and Adria plates is responsible of the active deformation in the Apennines. The most important outcomes of this study are: (i) During the interseismic phase the differential motion between Adriatic and Tyrrhenian domains seems to be accommodated in a narrow belt bordering the westward flank of the Sannio Mts, showing a 2 mm/y extension. (ii) The maximum extension does not follow the topographic high of the chain but is shifted toward the eastern outer belt. (iii) No significant GPS deformation is highlighted in correspondence of major and known fault systems where the GPS velocities appear almost steady. We propose that the observed coseismic displacements are only marginally explained by a slip on the MLF fault. The vertical directivity and depth distribution of the seismic sequence (Convertito et al., 2016), the vertical and horizontal heterogeneity of lower crust and upper mantle (Bisio et al., 2004; Di Stefano and Ciaccio, 2014), the high flux of CO2 degassing (Ventura et al., 2007, Chiarabba e Chiodini, 2013 ), the probable presence of pressurized CO2 bodies fed by fluids uprising from the mantle wedge (Improta et al.,2014 ), suggest instead that the seismic sequence could be caused by sub-vertical cracks that originate at the Moho interface and reach the bottom of the seismogenic layer (10km depth).

Description: DPC

Description: Unpublished

Description: San Francisco (USA)

Description: 2T. Tettonica attiva

Description: open

Description: In May-July 2012, a seismic sequence struck a broad area of the Po Plain Region in northern Italy. The sequence in- cluded two ML 〉5.5 mainshocks. The first one (ML 5.9) oc- curred near the city of Finale Emilia (ca. 30 km west of Ferrara) on May 20 at 02:03:53 (UTC), and the second (ML 5.8) occurred on May 29 at 7:00:03 (UTC), about 12 km south- west of the May 20 mainshock (Figure 1), near the city of Mirandola. The seismic sequence involved an area that ex- tended in an E-W direction for more than 50 km, and in- cluded seven ML ≥5.0 events and more than 2,300 ML 〉1.5 events (http://iside.rm.ingv.it). The focal mechanisms of the main events [Pondrelli et al. 2012, Scognamiglio et al. 2012, this volume] consistently showed compressional kinematics with E-W oriented reverse nodal planes. This sector of the Po Plain is known as a region charac- terized by slow deformation rates due to the northwards mo- tion of the northern Apennines fold-and-thrust belt, which is buried beneath the sedimentary cover of the Po Plain [Pi- cotti and Pazzaglia 2008, Toscani et al. 2009]. Early global po- sitioning system (GPS) measurements [Serpelloni et al. 2006] and the most recent updates [Devoti et al. 2011, Bennett et al. 2012] recognized that less than 2 mm/yr of SW-NE short- ening are accommodated across this sector of the Po Plain, in agreement with other present-day stress indicators [Mon- tone et al. 2012] and known active faults [Basili et al. 2008]. In the present study, we describe the GPS data used to study the coseismic deformation related to the May 20 and 29 mainshocks, and provide preliminary models of the two seismic sources, as inverted from consensus GPS coseismic deformation fields.

Description: Published

Description: 759-766

Description: 3.1. Fisica dei terremoti

Description: 3.2. Tettonica attiva

Description: JCR Journal

Description: open

Description: Subito dopo l’evento del 6 aprile 2009, come di consueto è stata realizzata una lunga e complessa indagine macrosismica, promossa dal gruppo operativo QUEST, che ha avuto inizialmente l’obiettivo di delimitare l’area di danneggiamento, a supporto delle attività di pronto intervento della Protezione Civile, e successivamente quello di classificare nel modo più accurato e capillare possibile, gli effetti prodotti dall’evento, particolarmente nelle aree danneggiate. A questo scopo è stata prodotta una stima utilizzando la scala MCS (Sieberg, 1930); in un secondo momento è stata rifinita l’indagine per una cinquantina di località dell’area maggiormente danneggiata (Is MCS〉VII), raccogliendo ed elaborando i dati in termini di scala macrosismica EMS98 (Grünthal, 1998). Per la complessità e la dimensione dei problemi affrontati, questo terremoto ha costituito un banco di prova di grande importanza per la macrosismologia italiana. In questo testo viene descritto il lavoro realizzato, discutendo in particolare alcuni aspetti che hanno messo alla prova le metodologie di indagine tradizionali (sistematiche irregolarità degli insediamenti monitorati, forti divergenze degli scenari di danno rispetto a quelli previsti dalle scale, difficile comparabilità con scenari storici, ecc.) e presentandone i risultati, in relazione ai parametri epicentrali che ne risultano e il loro contributo più diretto alla comprensione complessiva della sismicità dell’area.

Description: Published

Description: 49-55

Description: 1.11. TTC - Osservazioni e monitoraggio macrosismico del territorio nazionale

Description: N/A or not JCR

Description: open