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3. 3D geological modeling of the blind thrust system activated during the November 2022 Pesaro offshore seismic sequence (Adriatic sea, Italy).

Author

Maesano, Francesco Emanuele, primary, Buttinelli, Mauro, additional, Maffucci, Roberta, additional, Toscani, Giovanni, additional, Basili, Roberto, additional, Bonini, Lorenzo, additional, Burrato, Pierfrancesco, additional, Fedorik, Jakub, additional, Fracassi, Umberto, additional, Panara, Yuri, additional, Tarabusi, Gabriele, additional, Tiberti, Mara Monica, additional, Valensise, Gianluca, additional, Vallone, Roberto, additional, and Vannoli, Paola, additional

Published
2023
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6. Possible causes of arc development in the Apennines, central Italy

Author

Billi, Andrea and Tiberti, Mara Monica

Subjects
Apennines -- Environmental aspects, Mountains -- Environmental aspects, Earth sciences
Abstract

In central Italy, the geometry, kinematics, and tectonic evolution of the late Neogene Umbrian Arc, which is one of the main thrusts of the northern Apennines, have long been studied. Documented evidence for orogenic curvature includes verticalaxis rotations along both limbs of the arc and a positive orocline test along the entire arc. The cause of the curvature is, however, still unexplained. In this work, we focus our attention on the southern portion of the Umbrian Arc, the so-called Olevano-Antrodoco thrust. We analyze, in particular, gravity and seismic-reflection data and consider available paleomagnetic, stratigraphic, structural, and topographic evidence from the central Apennines to infer spatial extent, attitude, and surface effects of a midcrustal anticlinorium imaged in the CROP-11 deep seismic profile. The anticlinorium has horizontal dimensions of ~50 by 30 km, and it is located right beneath the Olevano-Antrodoco thrust. Stratigraphic, structural, and topographic evidence suggests that the anticlinorium produced a surface uplift during its growth in early Pliocene times. We propose an evolutionary model in which, during late Neogene time, the Olevano-Antrodoco thrust developed in an out-of-sequence fashion and underwent ~16[degrees] of clockwise rotation when the thrust ran into and was then raised and folded by the growing anticlinorium (late Messinian-early Pliocene time). This new model suggests a causal link between midcrustal folding and surficial orogenic curvature that is consistent with several available data sets from the northern and central Apennines; more evidence is, however, needed to fully test our hypothesis. Additionally, due to the occurrence of mid-crustal basement-involved thrusts in other orogens, this model may be a viable mechanism for arc formation elsewhere.

Published
2009

8. Comparing the tsunamigenic potential of two alternative earthquake rupture scenarios in the Ionian Sea

Author

Basili Roberto, Volpe Manuela, Maesano Francesco Emanuele, and Tiberti Mara Monica

Subjects
earthquake, tsunami, numerical simulation, Alfeo Fault System, Calabrian Arc, Sicily, Ionian Sea, Italy
Abstract

Description of a tsunami numerical simulations to verify if a hypothetical earthquake rupture on the Alfeo Fault System could generate a significant tsunami in the Ionian Sea., {"references":["Argnani, A., Armigliato, A., Pagnoni, G., Zaniboni, F., Tinti, S., and Bonazzi, C. (2012). Active tectonics along the submarine slope of south-eastern Sicily and the source of the 11 January 1693 earthquake and tsunami. Nat. Hazards Earth Syst. Sci. 12, 1311–1319. doi:10.5194/nhess-12-1311-2012.","Basili, R., Brizuela, B., Herrero, A., Iqbal, S., Lorito, S., Maesano, F. E., et al. (2019). NEAMTHM18 Documentation: the making of the TSUMAPS-NEAM Tsunami Hazard Model 2018. Roma, Italy: Istituto Nazionale di Geofisica e Vulcanologia (INGV); DOI: http://doi.org/10.5281/zenodo.3406625.","Basili, R., Tiberti, M. M., Kastelic, V., Romano, F., Piatanesi, A., Selva, J., et al. (2013). Integrating geologic fault data into tsunami hazard studies. Nat. Hazards Earth Syst. Sci. 13, 1025–1050. doi:10.5194/nhess-13-1025-2013.","Becker, J. J., Sandwell, D. T., Smith, W. H. F., Braud, J., Binder, B., Depner, J., et al. (2009). Global Bathymetry and Elevation Data at 30 Arc Seconds Resolution: SRTM30_PLUS. Mar. Geod. 32, 355–371. doi:10.1080/01490410903297766.","de la Asunción, M., Castro, M. J., Fernández-Nieto, E. D., Mantas, J. M., Acosta, S. O., and González-Vida, J. M. (2013). Efficient GPU implementation of a two waves TVD-WAF method for the two-dimensional one layer shallow water system on structured meshes. Comput. Fluids 80, 441–452. doi:10.1016/j.compfluid.2012.01.012.","Gallais, F., Graindorge, D., Gutscher, M.-A., and Klaeschen, D. (2013). Propagation of a lithospheric tear fault (STEP) through the western boundary of the Calabrian accretionary wedge offshore eastern Sicily (Southern Italy). Tectonophysics 602, 141–152. doi:10.1016/j.tecto.2012.12.026.","Guidoboni, E., Ferrari, G., Tarabusi, G., Sgattoni, G., Comastri, A., Mariotti, D., et al. (2019). CFTI5Med, the new release of the catalogue of strong earthquakes in Italy and in the Mediterranean area. Sci. Data 6, 80. doi:10.1038/s41597-019-0091-9.","Gutscher, M.-A., Dominguez, S., de Lepinay, B. M., Pinheiro, L., Gallais, F., Babonneau, N., et al. (2016). Tectonic expression of an active slab tear from high-resolution seismic and bathymetric data offshore Sicily (Ionian Sea). Tectonics 35, 39–54. doi:10.1002/2015TC003898.","Gutscher, M.-A., Kopp, H., Krastel, S., Bohrmann, G., Garlan, T., Zaragosi, S., et al. (2017). Active tectonics of the Calabrian subduction revealed by new multi-beam bathymetric data and high-resolution seismic profiles in the Ionian Sea (Central Mediterranean). Earth Planet. Sci. Lett. 461, 61–72. doi:10.1016/j.epsl.2016.12.020.","Gutscher, M.-A., Roger, J., Baptista, M.-A., Miranda, J. M., and Tinti, S. (2006). Source of the 1693 Catania earthquake and tsunami (southern Italy): New evidence from tsunami modeling of a locked subduction fault plane. Geophys. Res. Lett. 33, L08309. doi:10.1029/2005GL025442.","Kajiura, K. (1963). The leading wave of a tsunami. Bull Earthq Res Inst 41, 535–571.","Macías, J., Castro, M. J., Ortega, S., Escalante, C., and González-Vida, J. M. (2017). Performance Benchmarking of Tsunami-HySEA Model for NTHMP's Inundation Mapping Activities. Pure Appl. Geophys. 174, 3147–3183. doi:10.1007/s00024-017-1583-1.","Maesano, F. E., Tiberti, M. M., and Basili, R. (2017). The Calabrian Arc: three-dimensional modelling of the subduction interface. Sci. Rep. 7, 8887. doi:10.1038/s41598-017-09074-8.","Maesano, F. E., Tiberti, M. M., and Basili, R. (2020). Deformation and Fault Propagation at the Lateral Termination of a Subduction Zone: The Alfeo Fault System in the Calabrian Arc, Southern Italy. Front. Earth Sci. 8. doi:10.3389/feart.2020.00107.","Maramai, A., Brizuela, B., and Graziani, L. (2014). The Euro-Mediterranean Tsunami Catalogue. Ann. Geophys. 57. doi:10.4401/ag-6437.","Okada, Y. (1985). Surface deformation due to shear and tensile faults in a half-space. Bull. Seismol. Soc. Am. 75, 1135–1154.","Piatanesi, A., and Tinti, S. (1998). A revision of the 1693 eastern Sicily earthquake and tsunami. J. Geophys. Res. Solid Earth 103, 2749–2758. doi:10.1029/97JB03403.","Pirrotta, C., and Barbano, M. S. (2020). New Macroseismic and Morphotectonic Constraints to Infer a Fault Model for the 9 (Mw6.1) and 11 January (Mw7.3) 1693 Earthquakes (Southeastern Sicily). Front. Earth Sci. 8, 550851. doi:10.3389/feart.2020.550851.","Polonia, A., Torelli, L., Artoni, A., Carlini, M., Faccenna, C., Ferranti, L., et al. (2016). The Ionian and Alfeo–Etna fault zones: New segments of an evolving plate boundary in the central Mediterranean Sea? Tectonophysics 675, 69–90. doi:10.1016/j.tecto.2016.03.016.","Polonia, A., Torelli, L., Mussoni, P., Gasperini, L., Artoni, A., and Klaeschen, D. (2011). The Calabrian Arc subduction complex in the Ionian Sea: Regional architecture, active deformation, and seismic hazard. Tectonics 30, n/a-n/a. doi:10.1029/2010TC002821.","Rovida, A., Locati, M., Camassi, R., Lolli, B., and Gasperini, P. (2019). Catalogo Parametrico dei Terremoti Italiani (CPTI15), versione 2.0. 4760 earthquakes. doi:10.13127/CPTI/CPTI15.2.","Rovida, A., Locati, M., Camassi, R., Lolli, B., and Gasperini, P. (2020). The Italian earthquake catalogue CPTI15. Bull. Earthq. Eng. 18, 2953–2984. doi:10.1007/s10518-020-00818-y.","Scala, A., Lorito, S., Romano, F., Murphy, S., Selva, J., Basili, R., et al. (2020). Effect of Shallow Slip Amplification Uncertainty on Probabilistic Tsunami Hazard Analysis in Subduction Zones: Use of Long-Term Balanced Stochastic Slip Models. Pure Appl. Geophys. 177, 1497–1520. doi:10.1007/s00024-019-02260-x.","Selva, J., Tonini, R., Molinari, I., Tiberti, M. M., Romano, F., Grezio, A., et al. (2016). Quantification of source uncertainties in Seismic Probabilistic Tsunami Hazard Analysis (SPTHA). Geophys. J. Int. 205, 1780–1803. doi:10.1093/gji/ggw107.","Tinti, S., Armigliato, A., and Bortolucci, E. (2001). Contribution of tsunami data analysis to constrain the seismic source: the case of the 1693 eastern Sicily earthquake. J. Seismol. 5, 41–61. doi:10.1023/A:1009817601760.","Tonini, R., Basili, R., Maesano, F. E., Tiberti, M. M., Lorito, S., Romano, F., et al. (2020). Importance of earthquake rupture geometry on tsunami modelling: the Calabrian Arc subduction interface (Italy) case study. Geophys. J. Int. 223, 1805–1819. doi:10.1093/gji/ggaa409."]}

Published
2020
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9. Progetto SPOT - Sismicità Potenzialmente Innescabile Offshore e Tsunami: Report integrato di fine progetto

Author

Antoncecchi, Ilaria, Ciccone, Francesco, Dialuce, Gilberto, Grandi, Silvia, Terlizzeze, Franco, Di Bucci, Daniela, Dolce, Mauro, Argnani, Andrea, Mercorella, Alessandra, Pellegrini, Claudio, Rovere, Marzia, Armigliato, Alberto, Pagnoni, Gianluca, Paparo, Maria Ausilia, Tinti, Stefano, Zaniboni, Filippo, Basili, Roberto, Cavallaro, Danilo, Coltelli, Mauro, Firetto Carlino,Marco, Lipparini, Lorenzo, Lorito, Stefano, Maesano, Francesco Emanuele, Romano, Fabrizio, Scarfì, Luciano, Tiberti, Mara Monica, Volpe, Manuela, Fedorik, Jakub, Toscani, Giovanni, Borzi, Barbara, Faravelli, Marta, Bozzoni, Francesca, Pascale, Venanzio, Quaroni, Davide, Germagnoli, Fabio, Belliazzi, Stefano, Del Zoppo, Marta, Di Ludovico, Marco, Lignola, Gian Piero, and Prota, Andrea

Subjects
rischio sismico, vulnerabilità del costruito, frana sottomarina, Italia, Mare Ionio, Canale di Sicilia, scenario di impatto, terremoto, maremoto, rischio tsunami, tsunami, sismicità offshore, sicurezza marina, produzione idrocarburi, Mare Adriatico
Abstract

Il progetto SPOT (Sismicità Potenzialmente innescabile Offshore e Tsunami) è stato sviluppato con lo scopo di supportare le Autorità italiane nell'applicazione della Direttiva Europea sulla sicurezza delle operazioni in mare nel settore degli idrocarburi (2013/30/EU), su fondi di cui art. 35 del Decreto Legge 83/2012, e dei decreti italiani che ne derivano (Antoncecchi et al., 2019). Il progetto, della durata di 21 mesi, è stato ideato e finanziato dal Ministero dello Sviluppo Economico italiano – Direzione Generale per la sicurezza delle attività minerarie ed energetiche (DGS-UNMIG) nell’ambito della rete di ricerca CLYPEA, con il supporto tecnico del Dipartimento della Protezione Civile nazionale. Attività svolta nell'ambito del programma CLYPEA - Innovation Network for Future Energy, finanziato dal Ministero dello Sviluppo Economico su fondi per la "sicurezza offshore" ai sensi dell'art.35 D.L. 83/2012., Ministero dello sviluppo economico DGS-UNMIG Direzione generale per la sicurezza anche ambientale delle attività minerarie ed energetiche Ufficio nazionale minerario per gli idrocarburi e le georisorse Palazzo Piacentini - Via Veneto, 33 - 00187 Roma Tel. (+39) 06 4705 2859 Fax. (+39) 06 4788 7802 Email: dgsunmig.segreteria@mise.gov.itPEC: dgsunmig.dg@pec.mise.gov.it

Published
2020
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10. The Making of the NEAM Tsunami Hazard Model 2018 (NEAMTHM18)

Author

Basili, Roberto, Brizuela, Beatriz, Herrero, Andre, Iqbal, Sarfraz, Lorito, Stefano, Maesano, Francesco Emanuele, Murphy, Shane, Perfetti, Paolo, Romano, Fabrizio, Scala, Antonio, Selva, Jacopo, Taroni, Matteo, Tiberti, Mara Monica, Thio, Hong Kie, Tonini, Roberto, Volpe, Manuela, Glimsdal, Sylfest, Harbitz, Carl Bonnevie, Lovholt, Finn, Baptista, Maria Ana, Carrilho, Fernando, Matias, Luis Manuel, Omira, Rachid, Babeyko, Andrey, Hoechner, Andreas, Gurbuz, Mucahit, Pekcan, Onur, Yalciner, Ahmet, Canals, Miquel, Lastras, Galderic, Agalos, Apostolos, Papadopoulos, Gerassimos, Triantafyllou, Ioanna, Benchekroun, Sabah, Agrebi Jaouadi, Hedi, Ben Abdallah, Samir, Bouallegue, Atef, Hamdi, Hassene, Oueslati, Foued, Amato, Alessandro, Armigliato, Alberto, Behrens, Joern, Davies, Gareth, Di Bucci, Daniela, Dolce, Mauro, Geist, Eric, Gonzalez Vida, Jose Manuel, Gonzalez, Mauricio, Macias Sanchez, Jorge, Meletti, Carlo, Ozer Sozdinler, Ceren, Pagani, Marco, Parsons, Tom, Polet, Jascha, Power, William, Sorensen, Mathilde, Zaytsev, Andrey, Basili, Roberto, Brizuela, Beatriz, Herrero, Andre, Iqbal, Sarfraz, Lorito, Stefano, Maesano, Francesco Emanuele, Murphy, Shane, Perfetti, Paolo, Romano, Fabrizio, Scala, Antonio, Selva, Jacopo, Taroni, Matteo, Tiberti, Mara Monica, Thio, Hong Kie, Tonini, Roberto, Volpe, Manuela, Glimsdal, Sylfest, Harbitz, Carl Bonnevie, Lovholt, Finn, Baptista, Maria Ana, Carrilho, Fernando, Matias, Luis Manuel, Omira, Rachid, Babeyko, Andrey, Hoechner, Andreas, Gurbuz, Mucahit, Pekcan, Onur, Yalciner, Ahmet, Canals, Miquel, Lastras, Galderic, Agalos, Apostolos, Papadopoulos, Gerassimos, Triantafyllou, Ioanna, Benchekroun, Sabah, Agrebi Jaouadi, Hedi, Ben Abdallah, Samir, Bouallegue, Atef, Hamdi, Hassene, Oueslati, Foued, Amato, Alessandro, Armigliato, Alberto, Behrens, Joern, Davies, Gareth, Di Bucci, Daniela, Dolce, Mauro, Geist, Eric, Gonzalez Vida, Jose Manuel, Gonzalez, Mauricio, Macias Sanchez, Jorge, Meletti, Carlo, Ozer Sozdinler, Ceren, Pagani, Marco, Parsons, Tom, Polet, Jascha, Power, William, Sorensen, Mathilde, and Zaytsev, Andrey

Abstract

The NEAM Tsunami Hazard Model 2018 (NEAMTHM18) is a probabilistic hazard model for tsunamis generated by earthquakes. It covers the coastlines of the North-eastern Atlantic, the Mediterranean, and connected seas (NEAM). NEAMTHM18 was designed as a threephase project. The first two phases were dedicated to the model development and hazard calculations, following a formalized decision-making process based on a multiple-expert protocol. The third phase was dedicated to documentation and dissemination. The hazard assessment workflow was structured in Steps and Levels. There are four Steps: Step-1) probabilistic earthquake model; Step-2) tsunami generation and modeling in deep water; Step-3) shoaling and inundation; Step-4) hazard aggregation and uncertainty quantification. Each Step includes a different number of Levels. Level-0 always describes the input data; the other Levels describe the intermediate results needed to proceed from one Step to another. Alternative datasets and models were considered in the implementation. The epistemic hazard uncertainty was quantified through an ensemble modeling technique accounting for alternative models' weights and yielding a distribution of hazard curves represented by the mean and various percentiles. Hazard curves were calculated at 2,343 Points of Interest (P01) distributed at an average spacing of -20 km. Precalculated probability maps for five maximum inundation heights (MIH) and hazard intensity maps for five average return periods (ARP) were produced from hazard curves. In the entire NEAM Region, MIHs of several meters are rare but not impossible. Considering a 2% probability of exceedance in 50 years (ARP approximate to 2,475 years), the POIs with MIH >5 m are fewer than 1% and are all in the Mediterranean on Libya, Egypt, Cyprus, and Greece coasts. In the North-East Atlantic, POIs with MIH >3 m are on the coasts of Mauritania and Gulf of Cadiz. Overall, 30% of the POIs have MIH >1 m. NEAMTHM1 8 results and documentation

Published
2021
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12. The Making of the NEAM Tsunami Hazard Model 2018 (NEAMTHM18)

Author

Basili, Roberto, primary, Brizuela, Beatriz, additional, Herrero, André, additional, Iqbal, Sarfraz, additional, Lorito, Stefano, additional, Maesano, Francesco Emanuele, additional, Murphy, Shane, additional, Perfetti, Paolo, additional, Romano, Fabrizio, additional, Scala, Antonio, additional, Selva, Jacopo, additional, Taroni, Matteo, additional, Tiberti, Mara Monica, additional, Thio, Hong Kie, additional, Tonini, Roberto, additional, Volpe, Manuela, additional, Glimsdal, Sylfest, additional, Harbitz, Carl Bonnevie, additional, Løvholt, Finn, additional, Baptista, Maria Ana, additional, Carrilho, Fernando, additional, Matias, Luis Manuel, additional, Omira, Rachid, additional, Babeyko, Andrey, additional, Hoechner, Andreas, additional, Gürbüz, Mücahit, additional, Pekcan, Onur, additional, Yalçıner, Ahmet, additional, Canals, Miquel, additional, Lastras, Galderic, additional, Agalos, Apostolos, additional, Papadopoulos, Gerassimos, additional, Triantafyllou, Ioanna, additional, Benchekroun, Sabah, additional, Agrebi Jaouadi, Hedi, additional, Ben Abdallah, Samir, additional, Bouallegue, Atef, additional, Hamdi, Hassene, additional, Oueslati, Foued, additional, Amato, Alessandro, additional, Armigliato, Alberto, additional, Behrens, Jörn, additional, Davies, Gareth, additional, Di Bucci, Daniela, additional, Dolce, Mauro, additional, Geist, Eric, additional, Gonzalez Vida, Jose Manuel, additional, González, Mauricio, additional, Macías Sánchez, Jorge, additional, Meletti, Carlo, additional, Ozer Sozdinler, Ceren, additional, Pagani, Marco, additional, Parsons, Tom, additional, Polet, Jascha, additional, Power, William, additional, Sørensen, Mathilde, additional, and Zaytsev, Andrey, additional

Published
2021
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16. Insights on the European Fault-Source Model (EFSM20) as input to the 2020 update of the European Seismic Hazard Model (ESHM20)

Author

Basili, Roberto, primary, Danciu, Laurentiu, additional, Carafa, Michele Matteo Cosimo, additional, Kastelic, Vanja, additional, Maesano, Francesco Emanuele, additional, Tiberti, Mara Monica, additional, Vallone, Roberto, additional, Gracia, Eulalia, additional, Sesetyan, Karin, additional, Atanackov, Jure, additional, Sket-Motnikar, Barbara, additional, Zupančič, Polona, additional, Vanneste, Kris, additional, and Vilanova, Susana, additional

Published
2020
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18. Italy’s Database of Individual Seismogenic Sources (DISS), 20 years on: lessons learned from the construction of a SHA-oriented fault database

Author

Valensise, Gianluca, primary, Basili, Roberto, additional, Burrato, Pierfrancesco, additional, Fracassi, Umberto, additional, Kastelic, Vanja, additional, Maesano, Francesco Emanuele, additional, Tarabusi, Gabriele, additional, Tiberti, Mara Monica, additional, Vallone, Roberto, additional, and Vannoli, Paola, additional

Published
2020
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19. Insights on the European Fault-Source Model (EFSM20) as input to the 2020 update of the European Seismic Hazard Model (ESHM20)

Author

European Commission, Basili, Roberto, Danciu, Laurentiu, Carafa, Michele Matteo Cosimo, Kastelic, Vanja, Maesano, Francesco, Tiberti, Mara Monica, Vallone, Roberto, Gràcia, Eulàlia, Sesetyan, Karin, Atanackov, Jure, Sket-Motnikar, Barbara, Zupančič, Polona, Vanneste, Kris, Vilanova, Susana P., European Commission, Basili, Roberto, Danciu, Laurentiu, Carafa, Michele Matteo Cosimo, Kastelic, Vanja, Maesano, Francesco, Tiberti, Mara Monica, Vallone, Roberto, Gràcia, Eulàlia, Sesetyan, Karin, Atanackov, Jure, Sket-Motnikar, Barbara, Zupančič, Polona, Vanneste, Kris, and Vilanova, Susana P.

Abstract

The H2020 Project SERA (WP25-JRA3; http://www.sera-eu.org) is committed to updating and extending the 2013 European Seismic Hazard Model (ESHM13; Woessner et al., 2015, Bull. Earthquake Eng.) to form the basis of the next revision of the European seismic design code (CEN-EC8). Following the probabilistic framework established for ESHM13, the 2020 update (ESHM20) requires a continent-wide seismogenic model based on input from earthquake catalogs, tectonic information, and active faulting. The development of the European Fault-Source Model (EFSM20) fulfills the requirements related to active faulting. EFSM20 has two main categories of seismogenic faults: crustal faults and subduction systems. Crustal faults are meant to provide the hazard model with seismicity rates in a variety of tectonic contexts, including onshore and offshore active plate margins and plate interiors. Subduction systems are meant to provide the hazard model with both slab interface and intraslab seismicity rates. The model covers an area that encompasses a buffer of 300 km around all target European countries (except for Overseas Countries and Territories, OTCs), and a maximum of 300 km depth for slabs. The compilation of EFSM20 relies heavily on publicly available datasets and voluntarily contributed datasets spanning large regions, as well as solicited local contributions in specific areas of interest. The current status of the EFSM20 compilation includes 1,256 records of crustal faults for a total length of ~92,906 km and four subduction systems, namely the Gibraltar Arc, Calabrian Arc, Hellenic Arc, and Cyprus Arc. In this contribution, we present the curation of the main datasets and their associated information, the criteria for the prioritization and harmonization across the region, and the main strategy for transferring the earthquake fault-source input to the hazard modelers. The final version of EFSM20 will be made available through standard web services published in the EFEHR (http://ww

Published
2020

20. Hybrid Ground Motion Prediction Equations For Psha Purposes: The Study Case Of Southern Italy

Author

Lanzano Giovanni, D'Amico Maria, Felicetta Chiara, Puglia Rodolfo, Russo Emiliano, Santulin Marco, Tiberti Mara Monica, and Gomez-Capera Antonio

Subjects
PSHA, Hybrid-GMPEs, Southern Italy
Abstract

Proposal of the INGV-T3 Research Project 2015-2016 "HYbrid ground motion prediction equations forPSha purposes: the study case of souTHERn Italy". TheHYPSTHERproject is devoted to develop amethodological approach to retrieve ground motion prediction models for Southern Calabria and Sicily, based on the integration between recorded and synthetic data.&nbsp

Published
2018
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22. GdL ‘’MODELLO DI SOTTOSUOLO SEQUENZA DI AMATRICE’’

Author

Buttinelli, Mauro, Anselmi, Mario, Maesano, Francesco Emanuele, Doglioni, Carlo, Pantosti, Daniela, Di Bucci, Daniela, D'Ambrogi, Chiara, Bigi, Sabina, Improta, Luigi, Scrocca, Davide, Petracchini, Lorenzo, Mariucci, Maria Teresa, De Martini, Paolo Marco, Pucci, Stefano, Billi, Andrea, Ferri, Fernando, Bonini, Lorenzo, Tiberti, Mara Monica, Montone, Paola, Vannoli, Paola, Burrato, Pierfrancesco, Civico, Riccardo, Basili, Roberto, Fracassi, Umberto, Cavinato, Giampaolo, and Moscatelli, Massimiliano

Subjects
3D modelling, dati di sottosuolo, modelli geologici
Abstract

Gruppo composto da ricercatori e tecnologi di diversi enti di ricerca italiani con competenze sull’analisi di dati geologici di superficie e di sottosuolo per la ricostruzione di un modello geologico dell'area interessata dalla sequenza sismica del 24 agosto

Published
2016
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26. Il contributo dell’analisi gravimetrica alla ricostruzione dell’assetto strutturale profondo

Author

ORLANDO L., TIBERTI, MARA MONICA, Autori Vari, Orlando, L., and Tiberti, MARA MONICA

Abstract

This study, carried out in central-southern Italy, shows that surficial density contrasts markedly affect the regional gravity anomalies trend, conditioning both the reconstruction and the interpretation of this trend. Actually, Bouguer anomalies can be very dependent on density contrast in the upper crust, which can, in turn, greatly condition the Bouguer anomalies spatial distribution. Therefore the Bouguer anomalies distribution cannot be considered a direct expression of the deep structures. Maps of the Moho based on the Bouguer anomaly trend, or on filtered gravity anomalies, are affected by this uncertainty.To deal with this problem we applied a methodology that can be used to sort out the contributions of deep and surficial bodies. Such a methodology, called “stripping”, was applied in the present work. The obtained map of the deep-sourced gravity anomalies from this region provides a useful tool for investigating the deep features of the Apennines, revealing that also the deep structures of the Apennine chain are characterized by low cylindrism.

Published
2004

27. From Extension to Transcurrence: Regime Transition as a new key to Interpret Seismogenesis in the Southern Apennines (Italy)

Author

Fracassi, Umberto, Vannoli, Paola, Burrato, Pierfrancesco, Basili, Roberto, Tiberti, Mara Monica, Di Bucci, Daniela, and Valensise, Gianluca

Abstract

The backbone of the Southern Apennines is perhaps the largest seismic moment release area in Italy. The region is dominated by an extensional regime dating back to the Middle Pleistocene, with maximum extension striking SW-NE (i.e. orthogonal to the mountain belt). The full length (~ 200 km) of the mountain range has been the locus of several destructive earthquakes occurring in the uppermost 10-12 km of the crust. This seismicity is due to a well documented normal faulting mechanism. Instrumental earthquakes (e.g. 5 May 1990, 31 Oct 2002, 1 Nov 2002; all M 5.8) that have occurred in the foreland, east of the Southern Apennines, have posed new questions concerning seismogenic processes in southern Italy. Although of moderate magnitude, these events unveiled the presence of E-W striking, deeper (13-25 km) strike-slip faults. Recent studies suggest that these less known faults belong to inherited shear zones with a multi-phase tectonic history, the most recent phase being a right-lateral reactivation. The direction of the maximum horizontal extension of these faults (in a transcurrent regime) coincides with the maximum horizontal extension in the core of the Southern Apennines (in an extensional regime) and both are compatible with the general framework provided by the Africa-Europe convergence. However, the regional extent along strike of the E-W shear zones poses the issue of their continuity from the foreland towards the thrust-belt. The 1456 (M 6.9) and 1930 (M 6.7) earthquakes, that occurred just east of the main extensional axis, were caused by faults having a strike intermediate between the E-W, deeper strike-slip faults in the foreland and the NW-SE-trending, shallower normal faults in the extensional belt. Hence, the location and geometry of these seismogenic sources suggests that there could be a transition zone between the crustal volumes affected by the extensional and transcurrent regimes. To image such transition, we built a 3D model that incorporates data available from surface and subsurface geology (published and unpublished), seismogenic faults, seismicity, focal mechanisms, and gravity anomalies. We explored the mechanisms of fault interaction in the Southern Apennines between the extensional upper portion and the transcurrent deeper portion of the seismogenic layer. In particular, we studied (a) how the reactivation of regional shear zones interacts with an adjacent, although structurally independent, extensional belt; (b) at what depth range the interaction occurs; and (c1) whether oblique slip in earthquakes like the 1930 event is merely due to the geometry of the causative fault, or (c2) such geometry and kinematics are the result of oblique slip due to fault interaction. We propose that (a) the 1456 and 1930 earthquakes are the expression of the transition between the two tectonic regimes, and that (b) these events can be seen as templates of the seismogenic oblique-slip faulting that occurs at intermediate depths between the shallower extensional faults and the deeper strike-slip faults. These findings suggest that a transtensional faulting mechanism governs the release of major earthquakes in the transition zone between extensional and transcurrent domains., The 3D model whose rendering is shown in this poster was performed by inputting data from the seismogenic sources into 3D GeoModeller (© BRGM and Intrepid Geophysics, 2004). Assistance from Intrepid Geophysics during the construction of the 3D model is highly appreciated. Work financially supported by project DPC-INGV S2 (U.R. 1.1 and 2.4).

Published
2006
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28. Ground-Motion Variability for Single Site and Single Source through Deterministic Stochastic Method Simulations: Implications for PSHA.

Author

D'Amico, Maria, Tiberti, Mara Monica, Russo, Emiliano, Pacor, Francesca, and Basili, Roberto

Abstract

The ground-motion median and standard deviation of empirical ground-motion prediction equations (GMPEs) are usually poorly constrained in the near-source region due to the general lack of strong-motion records. Here we explore the use of a deterministic-stochastic simulation technique, specifically tailored to reproduce directivity effects, to evaluate the expected ground motion and its variability at a near-source site, and seek a strategy to overcome the known GMPEs limitations. To this end, we simulated a large number of equally likely scenario events for three earthquake magnitudes (Mw 7.0, 6.0, and 5.0) and various source-to-site distances. The variability of the explored synthetic ground motion is heteroscedastic, with smaller values for larger earthquakes. The standard deviation is comparable with empirical estimates for smaller events and reduces by 30%-40% for stronger earthquakes. We then illustrate how to incorporate directivity effects into probabilistic seismic-hazard analysis (PSHA). This goal is pursued by calibrating a set of synthetic GMPEs and reducing their aleatory variability (~50%) by including a predictive directivity term that depends on the apparent stress parameter obtained through the simulation method. Our results show that, for specific source-to-site configurations, the nonergodic PSHA is very sensitive to the additional epistemic uncertainty that may augment the exceedance probabilities when directivity effects are maximized. The proposed approach may represent a suitable way to compute more accurate hazard estimates. [ABSTRACT FROM AUTHOR]

Published
2017
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34. Hybrid GMPEs for Region-Specific PSHA in Southern Italy.

Author

D’Amico, Maria, Lanzano, Giovanni, Santulin, Marco, Puglia, Rodolfo, Felicetta, Chiara, Tiberti, Mara Monica, Gomez-Capera, Antonio Augusto, and Russo, Emiliano

Subjects
EARTHQUAKE hazard analysis, CHEMICAL plants
Abstract

This paper describes the main findings of the project HYPSTHER (HYbrid ground motion prediction equations for PSha purposes: the study case of souTHERn Italy; supported by the Italian Institute of Geophysics and Volcanology). The goal of the project is to develop a methodological approach to retrieve hybrid Ground Motion Prediction Equations (GMPEs) based on integration of recorded and synthetic data. This methodology was applied to the study area of southern Italy, focusing on the southern Calabria and Sicily regions. The target area was chosen due to the expected high seismic hazard levels, despite the low seismic activity in recent decades. In addition, along the coast of the study area, there are many critical infrastructures, such as chemical plants, refineries, and large ports, which strongly increase the risk of technological accidents induced by earthquakes. Through the synthetic data, the predictions of the hybrid GMPEs have been improved under near-field conditions, with respect to empirical models for moderate to large earthquakes. Attenuation at distances greater than 50 km is instead controlled by the empirical data, because attenuation is faster with distance. The aleatory variability of the hybrid models has strong impact on probabilistic seismic hazard assessment, as it is lower than the sigma of the empirical GMPEs. The use of the hybrid GMPEs specific for the study area can produce remarkable reductions in hazard levels for long-return periods, mainly due to changes in median predictions and reduction of the aleatory variability. [ABSTRACT FROM AUTHOR]

Published
2018
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36. Evolution of tear faults in subduction zones: an analogue modelling perspective

Author

Nicolò Bertone, Gian Andrea Pini, Lorenzo Bonini, Francesco Emanuele Maesano, Anna Del Ben, Mara Monica Tiberti, Roberto Basili, Bertone N., Bertone, Nicolò, Bonini, Lorenzo, Basili, Roberto, Del Ben, Anna, Maesano, Francesco Emanuele, Tiberti, Mara Monica, and Pini, Gian Andrea

Subjects
tear faults, wet clay, analogue modelling, Subduction, Analogue modelling, Perspective (graphical), Petrology, tear fault, Geology
Abstract

Tear faults are common structures in subduction zones, especially at slab edges, where they origin from differential forces applied to a subducting slab in areas close to the trench. Presence and geometry of tears have been sometimes inferred from bathymetric features, suggesting the abrupt lateral termination of the subduction zone.Differential forces acting at the subduction boundaries can be related to different mechanisms, such as slab retreat, differential velocities along plate margins, complex mantle flow, differential lateral rheology. As a result, plates down-warp and tear in a scissor-like motion, with both strike-slip and dip-slip kinematics.The goal of this work is to gain insights into the evolution of tear faults by adopting an analogue modelling approach and comparing the results with natural cases. In particular, we focus on the bathymetric observation made in subduction zones where the upper plate accretionary wedge is not well developed. Two scenarios were considered: 1) tear faults nucleating and evolving in a homogeneous setting, i.e. without large mechanical discontinuities (e.g., Tonga subduction zone); and 2) tear faults reactivating pre-existing strike-slip faults as an analogue of transform faults (e.g., South Sandwich subduction zone).The experimental apparatus was designed to reproduce the lateral propagation of a tear fault using two blocks: one entirely flat and the other with an inclined plane. Wet kaolin acts as the analogue of the intact rocks above a propagating tear fault.Our results revealed different evolutionary processes: in the homogeneous setting, the tear fault generates a symmetric subsidence zone with an axis perpendicular to the fault zone and a depocenter located in the centre; in the second case, the depocenter is located in front of the fault plane and the subsidence zone is asymmetric. Both cases depict a symmetrical Gaussian shape of the displacement profile, with the maximum displacement located at the centre of the fault. However, the maximum slip (Dmax) and the fault length (L) are both larger in the experiment involving a strong re-activation of the strike-slip fault than those in the case of the homogeneous setting.

Published
2020

37. Fossil landscapes and youthful seismogenic sources in the central Apennines: excerpts from the 24 August 2016, Amatrice earthquake and seismic hazard implications

Author

Pierfrancesco Burrato, Michele M. C. Carafa, Roberto Basili, Paola Vannoli, Mara Monica Tiberti, Lorenzo Bonini, Francesco Emanuele Maesano, Umberto Fracassi, Gianluca Valensise, Gabriele Tarabusi, Vanja Kastelic, Valensise, Gianluca, Vannoli, Paola, Basili, Roberto, Bonini, Lorenzo, Burrato, Pierfrancesco, Carafa, Michele Matteo Cosimo, Fracassi, Umberto, Kastelic, Vanja, Maesano, Francesco Emanuele, Tiberti, Mara Monica, and Tarabusi, Gabriele

Subjects
021110 strategic, defence & security studies, 2016 Amatrice earthquake, normal faulting, blind faulting, SAR interferometry, seismic hazard, lcsh:QC801-809, 0211 other engineering and technologies, 02 engineering and technology, Decoupling (cosmology), Active fault, lcsh:QC851-999, 010502 geochemistry & geophysics, earthquake geology, 01 natural sciences, lcsh:Geophysics. Cosmic physics, Geophysics, Seismic hazard, Interferometric synthetic aperture radar, Upper crust, lcsh:Meteorology. Climatology, Geophysic, Seismology, Geology, 0105 earth and related environmental sciences
Abstract

We show and discuss the similarities among the 2016 Amatrice (Mw 6.0), 1997 Colfiorito-Sellano (Mw 6.0-5.6) and 2009 L’Aquila (Mw 6.3) earthquakes. They all occurred along the crest of the central Apennines and were caused by shallow dipping faults between 3 and 10 km depth, as shown by their characteristic InSAR signature. We contend that these earthquakes delineate a seismogenic style that is characteristic of this portion of the central Apennines, where the upward propagation of seismogenic faults is hindered by the presence of pre-existing regional thrusts. This leads to an effective decoupling between the deeper seismogenic portion of the upper crust and its uppermost 3 km.The decoupling implies that active faults mapped at the surface do not connect with the seismogenic sources, and that their evolution may be controlled by passive readjustments to coseismic strains or even by purely gravitational motions. Seismic hazard analyses and estimates based on such faults should hence be considered with great caution as they may be all but representative of the true seismogenic potential.

Published
2016
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38. Imaging the tectonic framework of the 24 August 2016, amatrice (central Italy) earthquake sequence: New roles for old players?

Author

Paola Vannoli, Michele M. C. Carafa, Gianluca Valensise, Lorenzo Bonini, Roberto Basili, Francesco Emanuele Maesano, Mara Monica Tiberti, Pierfrancesco Burrato, Umberto Fracassi, Gabriele Tarabusi, Vanja Kastelic, Bonini, Lorenzo, Maesano, Francesco Emanuele, Basili, Roberto, Burrato, Pierfrancesco, Carafa, Michele Matteo Cosimo, Fracassi, Umberto, Kastelic, Vanja, Tarabusi, Gabriele, Tiberti, Mara Monica, Vannoli, Paola, and Valensise, Gianluca

Subjects
Extensional fault, 010504 meteorology & atmospheric sciences, lcsh:QC801-809, Thrust, lcsh:QC851-999, structural geology, 010502 geochemistry & geophysics, Blind thrust earthquake, 01 natural sciences, Amatrice earthquake, Nappe, Thrust tectonics, Tectonics, lcsh:Geophysics. Cosmic physics, Geophysics, structural geology, Geophysics, Thrust fault, lcsh:Meteorology. Climatology, Seismology, Geology, Aftershock, 0105 earth and related environmental sciences
Abstract

We reconstruct the tectonic framework of the 24 August 2016, Amatrice earthquake. At least three main faults, including an older thrust fault (Sibillini Thrust), played an active role in the sequence. The mainshock nucleated and propagated along an extensional fault located in the footwall of the Sibillini Thrust, but due to the preliminary nature of the data the role of this thrust is still unclear. We illustrate two competing solutions: 1) the coseismic rupture started along an extensional fault and then partially used the thrust plane in extensional motion; 2) the thrust fault acted as an upper barrier to the propagation of the mainshock rupture, but was partially reactivated during the aftershock sequence. In both cases our tectonic reconstruction suggests an active role of the thrust fault, providing yet another example of how structures inherited from older tectonic phases may control the mainshock ruptures and the long-term evolution of younger seismogenic faults.

Published
2016

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