Your search keyword '"Piatanesi A."' showing total 141 results

1. A first appraisal of the seismogenic and tsunamigenic potential of the largest fault systems in the westernmost Mediterranean

Author

Gómez de la Peña, Laura, Gràcia, Eulàlia, Maesano, Francesco Emanuele, Basili, Roberto, Kopp, Heidrun, Sánchez-Serra, Cristina, Scala, Antonio, Romano, Fabrizio, Volpe, Manuela, Piatanesi, Alessio, and R. Ranero, César

Published

2022

2. Characterization of fault plane and coseismic slip for the 2 May 2020, Mw 6.6 Cretan Passage earthquake from tide gauge tsunami data and moment tensor solutions

Author

E. Baglione, S. Lorito, A. Piatanesi, F. Romano, R. Basili, B. Brizuela, R. Tonini, M. Volpe, H. B. Bayraktar, and A. Amato

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

We present a source solution for the tsunami generated by the Mw 6.6 earthquake that occurred on 2 May 2020, about 80 km offshore south of Crete, in the Cretan Passage, on the shallow portion of the Hellenic Arc subduction zone (HASZ). The tide gauges recorded this local tsunami on the southern coast of Crete and Kasos island. We used Crete tsunami observations to constrain the geometry and orientation of the causative fault, the rupture mechanism, and the slip amount. We first modelled an ensemble of synthetic tsunami waveforms at the tide gauge locations, produced for a range of earthquake parameter values as constrained by some of the available moment tensor solutions. We allow for both a splay and a back-thrust fault, corresponding to the two nodal planes of the moment tensor solution. We then measured the misfit between the synthetic and the Ierapetra observed marigram for each source parameter set. Our results identify the shallow, steeply dipping back-thrust fault as the one producing the lowest misfit to the tsunami data. However, a rupture on a lower angle fault, possibly a splay fault, with a sinistral component due to the oblique convergence on this segment of the HASZ, cannot be completely ruled out. This earthquake reminds us that the uncertainty regarding potential earthquake mechanisms at a specific location remains quite significant. In this case, for example, it is not possible to anticipate if the next event will be one occurring on the subduction interface, on a splay fault, or on a back-thrust, which seems the most likely for the event under investigation. This circumstance bears important consequences because back-thrust and splay faults might enhance the tsunamigenic potential with respect to the subduction interface due to their steeper dip. Then, these results are relevant for tsunami forecasting in the framework of both the long-term hazard assessment and the early warning systems.

Published

2021

3. Probabilistic tsunami forecasting for early warning

Author

J. Selva, S. Lorito, M. Volpe, F. Romano, R. Tonini, P. Perfetti, F. Bernardi, M. Taroni, A. Scala, A. Babeyko, F. Løvholt, S. J. Gibbons, J. Macías, M. J. Castro, J. M. González-Vida, C. Sánchez-Linares, H. B. Bayraktar, R. Basili, F. E. Maesano, M. M. Tiberti, F. Mele, A. Piatanesi, and A. Amato

Subjects

Science

Abstract

Probabilistic tsunami forecasting (PTF) defines an approach to tsunami early warning based on uncertainty quantification, enhancing forecast accuracy and enabling rational decision making. PTF is here developed for near-source tsunami warning, and tested in hindcasting mode over a wide range of past earthquakes.

Published

2021

4. Tsunami risk management for crustal earthquakes and non-seismic sources in Italy

Author

Selva, J., Amato, A., Armigliato, A., Basili, R., Bernardi, F., Brizuela, B., Cerminara, M., de’ Micheli Vitturi, M., Di Bucci, D., Di Manna, P., Esposti Ongaro, T., Lacanna, G., Lorito, S., Løvholt, F., Mangione, D., Panunzi, E., Piatanesi, A., Ricciardi, A., Ripepe, M., Romano, F., Santini, M., Scalzo, A., Tonini, R., Volpe, M., and Zaniboni, F.

Published

2021

5. Effect of Shallow Slip Amplification Uncertainty on Probabilistic Tsunami Hazard Analysis in Subduction Zones: Use of Long-Term Balanced Stochastic Slip Models

Author

Scala, A., Lorito, S., Romano, F., Murphy, S., Selva, J., Basili, R., Babeyko, A., Herrero, A., Hoechner, A., Løvholt, F., Maesano, F. E., Perfetti, P., Tiberti, M. M., Tonini, R., Volpe, M., Davies, G., Festa, G., Power, W., Piatanesi, A., and Cirella, A.

Published

2020

6. Testing Tsunami Inundation Maps for Evacuation Planning in Italy

Author

Roberto Tonini, Pio Di Manna, Stefano Lorito, Jacopo Selva, Manuela Volpe, Fabrizio Romano, Roberto Basili, Beatriz Brizuela, Manuel J. Castro, Marc de la Asunción, Daniela Di Bucci, Mauro Dolce, Alexander Garcia, Steven J. Gibbons, Sylfest Glimsdal, José M. González-Vida, Finn Løvholt, Jorge Macías, Alessio Piatanesi, Luca Pizzimenti, Carlos Sánchez-Linares, and Eutizio Vittori

Subjects

tsunamis, inundation maps, early warning, probabilistic hazard, numerical modeling, Italy, Science

Abstract

Inundation maps are a fundamental tool for coastal risk management and in particular for designing evacuation maps and evacuation planning. These in turn are a necessary component of the tsunami warning systems’ last-mile. In Italy inundation maps are informed by a probabilistic tsunami hazard model. Based on a given level of acceptable risk, Italian authorities in charge for this task recommended to consider, as design hazard intensity, the average return period of 2500 years and the 84th percentile of the hazard model uncertainty. An available, regional-scale tsunami hazard model was used that covers the entire Italian coastline. Safety factors based on analysis of run-up variability and an empirical coastal dissipation law on a digital terrain model (DTM) were applied to convert the regional hazard into the design run-up and the corresponding evacuation maps with a GIS-based approach. Since the regional hazard cannot fully capture the local-scale variability, this simplified and conservative approach is considered a viable and feasible practice to inform local coastal risk management in the absence of high-resolution hazard models. The present work is a first attempt to quantify the uncertainty stemming from such procedure. We compare the GIS-based inundation maps informed by a regional model with those obtained from a local high-resolution hazard model. Two locations on the coast of eastern Sicily were considered, and the local hazard was addressed with the same seismic model as the regional one, but using a higher-resolution DTM and massive numerical inundation calculations with the GPU-based Tsunami-HySEA nonlinear shallow water code. This study shows that the GIS-based inundation maps used for planning deal conservatively with potential hazard underestimation at the local scale, stemming from typically unmodeled uncertainties in the numerical source and tsunami evolution models. The GIS-based maps used for planning fall within the estimated “error-bar” due to such uncertainties. The analysis also demonstrates the need to develop local assessments to serve very specific risk mitigation actions to reduce the uncertainty. More in general, the presented case-studies highlight the importance to explore ways of dealing with uncertainty hidden within the high-resolution numerical inundation models, e.g., related to the crude parameterization of the bottom friction, or the inaccuracy of the DTM.

Published

2021

7. Benchmarking the Optimal Time Alignment of Tsunami Waveforms in Nonlinear Joint Inversions for the Mw 8.8 2010 Maule (Chile) Earthquake

Author

F. Romano, S. Lorito, T. Lay, A. Piatanesi, M. Volpe, S. Murphy, and R. Tonini

Subjects

The 2010 Maule earthquake, joint inversion, tsunami, optimal time alignment, benchmark, Science

Abstract

Finite-fault models for the 2010 Mw 8.8 Maule, Chile earthquake indicate bilateral rupture with large-slip patches located north and south of the epicenter. Previous studies also show that this event features significant slip in the shallow part of the megathrust, which is revealed through correction of the forward tsunami modeling scheme used in tsunami inversions. The presence of shallow slip is consistent with the coseismic seafloor deformation measured off the Maule region adjacent to the trench and confirms that tsunami observations are particularly important for constraining far-offshore slip. Here, we benchmark the method of Optimal Time Alignment (OTA) of the tsunami waveforms in the joint inversion of tsunami (DART and tide-gauges) and geodetic (GPS, InSAR, land-leveling) observations for this event. We test the application of OTA to the tsunami Green’s functions used in a previous inversion. Through a suite of synthetic tests we show that if the bias in the forward model is comprised only of delays in the tsunami signals, the OTA can correct them precisely, independently of the sensors (DART or coastal tide-gauges) and, to the first-order, of the bathymetric model used. The same suite of experiments is repeated for the real case of the 2010 Maule earthquake where, despite the results of the synthetic tests, DARTs are shown to outperform tide-gauges. This gives an indication of the relative weights to be assigned when jointly inverting the two types of data. Moreover, we show that using OTA is preferable to subjectively correcting possible time mismatch of the tsunami waveforms. The results for the source model of the Maule earthquake show that using just the first-order modeling correction introduced by OTA confirms the bilateral rupture pattern around the epicenter, and, most importantly, shifts the inferred northern patch of slip to a shallower position consistent with the slip models obtained by applying more complex physics-based corrections to the tsunami waveforms. This is confirmed by a slip model refined by inverting geodetic and tsunami data complemented with a denser distribution of GPS data nearby the source area. The models obtained with the OTA method are finally benchmarked against the observed seafloor deformation off the Maule region. We find that all of the models using the OTA well predict this offshore coseismic deformation, thus overall, this benchmarking of the OTA method can be considered successful.

Published

2020

8. Near-source high-rate GPS, strong motion and InSAR observations to image the 2015 Lefkada (Greece) Earthquake rupture history

Author

Antonio Avallone, Antonella Cirella, Daniele Cheloni, Cristiano Tolomei, Nikos Theodoulidis, Alessio Piatanesi, Pierre Briole, and Athanassios Ganas

Subjects

Medicine, Science

Abstract

Abstract The 2015/11/17 Lefkada (Greece) earthquake ruptured a segment of the Cephalonia Transform Fault (CTF) where probably the penultimate major event was in 1948. Using near-source strong motion and high sampling rate GPS data and Sentinel-1A SAR images on two tracks, we performed the inversion for the geometry, slip distribution and rupture history of the causative fault with a three-step self-consistent procedure, in which every step provided input parameters for the next one. Our preferred model results in a ~70° ESE-dipping and ~13° N-striking fault plane, with a strike-slip mechanism (rake ~169°) in agreement with the CTF tectonic regime. This model shows a bilateral propagation spanning ~9 s with the activation of three main slip patches, characterized by rise time and peak slip velocity in the ranges 2.5–3.5 s and 1.4–2.4 m/s, respectively, corresponding to 1.2–1.8 m of slip which is mainly concentrated in the shallower ( 6) earthquakes to the northern and to the southern boundaries of the 2015 causative fault cannot be excluded.

Published

2017

9. Fast evaluation of tsunami scenarios: uncertainty assessment for a Mediterranean Sea database

Author

I. Molinari, R. Tonini, S. Lorito, A. Piatanesi, F. Romano, D. Melini, A. Hoechner, J. M. Gonzàlez Vida, J. Maciás, M. J. Castro, and M. de la Asunción

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

We present a database of pre-calculated tsunami waveforms for the entire Mediterranean Sea, obtained by numerical propagation of uniformly spaced Gaussian-shaped elementary sources for the sea level elevation. Based on any initial sea surface displacement, the database allows the fast calculation of full waveforms at the 50 m isobath offshore of coastal sites of interest by linear superposition. A computationally inexpensive procedure is set to estimate the coefficients for the linear superposition based on the potential energy of the initial elevation field. The elementary sources size and spacing is fine enough to satisfactorily reproduce the effects of M> = 6.0 earthquakes. Tsunami propagation is modelled by using the Tsunami-HySEA code, a GPU finite volume solver for the non-linear shallow water equations. Like other existing methods based on the initial sea level elevation, the database is independent on the faulting geometry and mechanism, which makes it applicable in any tectonic environment. We model a large set of synthetic tsunami test scenarios, selected to explore the uncertainty introduced when approximating tsunami waveforms and their maxima by fast and simplified linear combination. This is the first time to our knowledge that the uncertainty associated to such a procedure is systematically analysed and that relatively small earthquakes are considered, which may be relevant in the near-field of the source in a complex tectonic setting. We find that non-linearity of tsunami evolution affects the reconstruction of the waveforms and of their maxima by introducing an almost unbiased (centred at zero) error distribution of relatively modest extent. The uncertainty introduced by our approximation can be in principle propagated to forecast results. The resulting product then is suitable for different applications such as probabilistic tsunami hazard analysis, tsunami source inversions and tsunami warning systems.

Published

2016

10. Tsunami forecasting variability as resulting from slip models obtained by geophysical data inversion and by a Phase Variation Method

Author

Romano, F., Catalan, P., Lorito, S., Escalante Sanchez, C., Atzori, S., Lay, T., Tonini, R., Volpe, M., Piatanesi, A., Macias Sanchez, J., and Castro Diaz, M.

Abstract

The accurate estimate of the tsunami forecast is crucial in Tsunami Early Warning Systems (TEWS) framework. However, the inherent uncertainties associated with the tsunami source estimation in real-time make tsunami forecasting challenging.In this study, we consider the South American subduction zone, one of the most seismically active regions in the world, where in the last 15 years occurred, three M8+ tsunamigenic earthquakes; in particular, we focus on the 2014 Mw 8.1 Iquique event.Here, we compare the tsunami forecasting for the Chilean coast as resultingi)from the coseismic slip model obtained by geophysical data inversion andii)from an expeditious method for the tsunami source estimation, based on an extension of the well-known spectral approach.In the former method, we estimate the slip distribution of the 2014 Iquique earthquake by jointly inverting tsunami waveforms and GPS data; on the other hand, a set of stochastic slip models in the latter is generated through a Phase Variation Method (PVM), where realizations are obtained from both the wavenumber and phase spectra of the source.We also evaluate how the different physics complexity included in the tsunami modelling (e.g. by including dispersion or not) can be mapped into the tsunami forecasting uncertainty. Finally, as an independent check, we compare the predicted deformation field from the slip models (inverted or by PVM) with the RADARSAT-2 InSAR data., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published

2023

11. Appraising the Early-est earthquake monitoring system for tsunami alerting at the Italian Candidate Tsunami Service Provider

Author

F. Bernardi, A. Lomax, A. Michelini, V. Lauciani, A. Piatanesi, and S. Lorito

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

In this paper we present and discuss the performance of the procedure for earthquake location and characterization implemented in the Italian Candidate Tsunami Service Provider at the Istituto Nazionale di Geofisica e Vulcanologia (INGV) in Rome. Following the ICG/NEAMTWS guidelines, the first tsunami warning messages are based only on seismic information, i.e., epicenter location, hypocenter depth, and magnitude, which are automatically computed by the software Early-est. Early-est is a package for rapid location and seismic/tsunamigenic characterization of earthquakes. The Early-est software package operates using offline-event or continuous-real-time seismic waveform data to perform trace processing and picking, and, at a regular report interval, phase association, event detection, hypocenter location, and event characterization. Early-est also provides mb, Mwp, and Mwpd magnitude estimations. mb magnitudes are preferred for events with Mwp ≲ 5.8, while Mwpd estimations are valid for events with Mwp ≳ 7.2. In this paper we present the earthquake parameters computed by Early-est between the beginning of March 2012 and the end of December 2014 on a global scale for events with magnitude M ≥ 5.5, and we also present the detection timeline. We compare the earthquake parameters automatically computed by Early-est with the same parameters listed in reference catalogs. Such reference catalogs are manually revised/verified by scientists. The goal of this work is to test the accuracy and reliability of the fully automatic locations provided by Early-est. In our analysis, the epicenter location, hypocenter depth and magnitude parameters do not differ significantly from the values in the reference catalogs. Both mb and Mwp magnitudes show differences to the reference catalogs. We thus derived correction functions in order to minimize the differences and correct biases between our values and the ones from the reference catalogs. Correction of the Mwp distance dependency is particularly relevant, since this magnitude refers to the larger and probably tsunamigenic earthquakes. Mwp values at stations with epicentral distance Δ ≲ 30° are significantly overestimated with respect to the CMT-global solutions, whereas Mwp values at stations with epicentral distance Δ ≳ 90° are slightly underestimated. After applying such distance correction the Mwp provided by Early-est differs from CMT-global catalog values of about δ Mwp ≈ 0.0 ∓ 0.2. Early-est continuously acquires time-series data and updates the earthquake source parameters. Our analysis shows that the epicenter coordinates and the magnitude values converge within less than 10 min (5 min in the Mediterranean region) toward the stable values. Our analysis shows that we can compute Mwp magnitudes that do not display short epicentral distance dependency overestimation, and we can provide robust and reliable earthquake source parameters to compile tsunami warning messages within less than 15 min after the event origin time.

Published

2015

12. Source of the 6 February 2013 Mw = 8.0 Santa Cruz Islands Tsunami

Author

F. Romano, I. Molinari, S. Lorito, and A. Piatanesi

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

On 6 February 2013 an Mw = 8.0 subduction earthquake occurred close to Santa Cruz Islands at the transition between the Solomon and the New Hebrides Trench. The ensuing tsunami caused significant inundation on the closest Nendo Island. The seismic source was studied with teleseismic broadband P-wave inversion optimized with tsunami forward modelling at DART buoys (Lay et al., 2013) and with inversion of teleseismic body and surface waves (Hayes et al., 2014a). The two studies also use different hypocentres and different planar fault models and found quite different slip models. In particular, Hayes et al. (2014a) argued for an aseismic slip patch SE from the hypocentre. We here develop a 3-D model of the fault surface from seismicity analysis and retrieve the tsunami source by inverting DART and tide-gauge data. Our tsunami source model features a main slip patch (peak value of ~ 11 m) SE of the hypocentre and reaching the trench. The rake direction is consistent with the progressively more oblique plate convergence towards the Solomon trench. The tsunami source partially overlaps the hypothesized aseismic slip area, which then might have slipped coseismically.

Published

2015

13. Characterization of fault plane and coseismic slip for the 2 May 2020, Mw 6.6 Cretan Passage earthquake from tide gauge tsunami data and moment tensor solutions

Author

Baglione, E, Lorito, S, Piatanesi, A, Romano, F, Basili, R, Brizuela, B, Tonini, R, Volpe, M, Bayraktar, HB, Amato, A, Baglione, E, Lorito, S, Piatanesi, A, Romano, F, Basili, R, Brizuela, B, Tonini, R, Volpe, M, Bayraktar, HB, and Amato, A

Subjects

natural hazards, tsunami hazard, seismic source, tsunami early warning, Mediterranean

Abstract

We present a source solution for the tsunami generated by the Mw 6.6 earthquake that occurred on 2 May 2020, about 80 km offshore south of Crete, in the Cretan Passage, on the shallow portion of the Hellenic Arc subduction zone (HASZ). The tide gauges recorded this local tsunami on the southern coast of Crete and Kasos island. We used Crete tsunami observations to constrain the geometry and orientation of the causative fault, the rupture mechanism, and the slip amount. We first modelled an ensemble of synthetic tsunami waveforms at the tide gauge locations, produced for a range of earthquake parameter values as constrained by some of the available moment tensor solutions. We allow for both a splay and a back-thrust fault, corresponding to the two nodal planes of the moment tensor solution. We then measured the misfit between the synthetic and the Ierapetra observed marigram for each source parameter set. Our results identify the shallow, steeply dipping back-thrust fault as the one producing the lowest misfit to the tsunami data. However, a rupture on a lower angle fault, possibly a splay fault, with a sinistral component due to the oblique convergence on this segment of the HASZ, cannot be completely ruled out. This earthquake reminds us that the uncertainty regarding potential earthquake mechanisms at a specific location remains quite significant. In this case, for example, it is not possible to anticipate if the next event will be one occurring on the subduction interface, on a splay fault, or on a back-thrust, which seems the most likely for the event under investigation. This circumstance bears important consequences because back-thrust and splay faults might enhance the tsunamigenic potential with respect to the subduction interface due to their steeper dip. Then, these results are relevant for tsunami forecasting in the framework of both the long-term hazard assessment and the early warning systems.

Published

2021

14. Tsunami riskmanagement for crustal earthquakes and non-seismic sources in Italy

Author

D. Mangione, Daniela Di Bucci, M. Santini, M. de’ Micheli Vitturi, Roberto Basili, Maurizio Ripepe, Fabrizio Romano, P. Di Manna, Alessandro Amato, Jacopo Selva, Finn Løvholt, Alberto Armigliato, A. Ricciardi, Filippo Zaniboni, A. Scalzo, Alessio Piatanesi, Stefano Lorito, E. Panunzi, Beatriz Brizuela, Matteo Cerminara, T. Esposti Ongaro, Giorgio Lacanna, Manuela Volpe, Fabrizio Bernardi, Roberto Tonini, Jacopo Selva, Alessandro Amato, Alberto Armigliato, Roberto Basili, Fabrizio Bernardi, Beatriz Brizuela, Matteo Cerminara, Mattia de’Micheli Vitturi, Daniela Di Bucci, Pio Di Manna, Tomaso Esposti Ongaro, Giorgio Lacanna, Stefano Lorito, Finn Løvholt, Domenico Mangione, Eleonora Panunzi, Alessio Piatanesi, A. Ricciardi, Maurizio Ripepe, Fabrizio Romano, M. Santini, Antonella Scalzo, Roberto Tonini, Manuela Volpe, Filippo Zaniboni, Selva, J., Amato, A., Armigliato, A., Basili, R., Bernardi, F., Brizuela, B., Cerminara, M., de' Micheli Vitturi, M., Di Bucci, D., Di Manna, P., Esposti Ongaro, T., Lacanna, G., Lorito, S., L(o)vholt, F., Mangione, D., Panunzi, E., Piatanesi, A., Ricciardi, A., Ripepe, M., Romano, F., Santini, M., Scalzo, A., Tonini, R., Volpe, M., and Zaniboni, F.

Subjects

Physics, geography, geography.geographical_feature_category, Warning system, Subduction, business.industry, General Physics and Astronomy, Landslide, Hazard, Italian coasts, NEAM, Tsunami, Warning, Tectonics, Tsunami warning system, Volcano, business, Tsunami · Hazard · Warning · NEAM · Italian coasts, Seismology, Risk management

Abstract

Destructive tsunamis are most often generated by large earthquakes occurring at subduction interfaces, but also other “atypical” sources—defined as crustal earthquakes and non-seismic sources altogether—may cause significant tsunami threats. Tsunamis may indeed be generated by different sources, such as earthquakes, submarine or coastal landslides, volcano-related phenomena, and atmospheric perturbations. The consideration of atypical sources is important worldwide, but it is especially prominent in complex tectonic settings such as the Mediterranean, the Caribbean, or the Indonesian archipelago. The recent disasters in Indonesia in 2018, caused by the Palu-Sulawesi magnitude Mw 7.5 crustal earthquake and by the collapse of the Anak-Krakatau volcano, recall the importance of such sources. Dealing with atypical sources represents a scientific, technical, and computational challenge, which depends on the capability of quantifying and managing uncertainty efficiently and of reducing it with accurate physical modelling. Here, we first introduce the general framework in which tsunami threats are treated, and then we review the current status and the expected future development of tsunami hazard quantifications and of the tsunami warning systems in Italy, with a specific focus on the treatment of atypical sources. In Italy, where the memory of historical atypical events like the 1908 Messina earthquake or the relatively recent 2002 Stromboli tsunami is still vivid, specific attention has been indeed dedicated to the progressive development of innovative strategies to deal with such atypical sources. More specifically, we review the (national) hazard analyses and their application for coastal planning, as well as the two operating tsunami warning systems: the national warning system for seismically generated tsunamis (SiAM), whose upstream component—the CAT-INGV—is also a Tsunami Service Provider of the North-eastern Atlantic, the Mediterranean and connected seas Tsunami Warning System (NEAMTWS) coordinated by the Intergovernmental Coordination Group established by the Intergovernmental Oceanographic Commission (IOC) of UNESCO, and the local warning system for tsunamis generated by volcanic slides along the Sciara del Fuoco of Stromboli volcano. Finally, we review the state of knowledge about other potential tsunami sources that may generate significant tsunamis for the Italian coasts, but that are not presently considered in existing tsunami warning systems. This may be considered the first step towards their inclusion in the national tsunami hazard and warning programs.

Published

2021

15. Integrating geologic fault data into tsunami hazard studies

Author

R. Basili, M. M. Tiberti, V. Kastelic, F. Romano, A. Piatanesi, J. Selva, and S. Lorito

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

We present the realization of a fault-source data set designed to become the starting point in regional-scale tsunami hazard studies. Our approach focuses on the parametric fault characterization in terms of geometry, kinematics, and assessment of activity rates, and includes a systematic classification in six justification levels of epistemic uncertainty related with the existence and behaviour of fault sources. We set up a case study in the central Mediterranean Sea, an area at the intersection of the European, African, and Aegean plates, characterized by a complex and debated tectonic structure and where several tsunamis occurred in the past. Using tsunami scenarios of maximum wave height due to crustal earthquakes (Mw=7) and subduction earthquakes (Mw=7 and Mw=8), we illustrate first-order consequences of critical choices in addressing the seismogenic and tsunamigenic potentials of fault sources. Although tsunamis generated by Mw=8 earthquakes predictably affect the entire basin, the impact of tsunamis generated by Mw=7 earthquakes on either crustal or subduction fault sources can still be strong at many locales. Such scenarios show how the relative location/orientation of faults with respect to target coastlines coupled with bathymetric features suggest avoiding the preselection of fault sources without addressing their possible impact onto hazard analysis results.

Published

2013

16. Joint Inversion of Geodetic and Strong Motion Data for the 2012, Mw 6.1–6.0, May 20th and May 29th, Northern Italy Earthquakes: Source Models and Seismotectonic Interpretation.

Author

Improta, L., Cirella, A., Pezzo, G., Molinari, I., and Piatanesi, A.

Subjects

EARTHQUAKE aftershocks, SEISMIC reflection method, SEISMOTECTONICS, EARTHQUAKES, THRUST faults (Geology), GEOLOGICAL modeling, CARBONATE rocks, THRUST belts (Geology)

Abstract

We present the first rupture models of the two mainshocks of the 2012 northern Italy sequence, determined by jointly inverting seismic and geodetic data. We aim at providing new insights into the mainshocks for which contrasting seismotectonic interpretations are proposed in literature. Sources' geometric parameters were constrained by seismic reflection profiles, 3‐D relocations and focal mechanisms of mainshocks/aftershocks. Site‐specific velocity profiles were used to model accelerograms affected by strong propagation effects related to the Po basin. Our source models differ significantly from previous ones relying on either seismic or geodetic data. Their comparison against geological sections and aftershock distribution provides new insights about the ruptured thrust faults. The May 20th Mw6.1 mainshock activated the Middle Ferrara thrust‐ramp dipping ∼45° SSW‐wards, breaking a main eastern slip patch 4–15 km deep in Mesozoic carbonates (maximum slip 0.7–0.8 m) and Paleozoic‐Triassic basement rocks, and a small western patch in the basement. The May 29th Mw6.0 mainshock featured two separated asperities along the Mirandola thrust‐ramp dipping ∼42° S‐wards: an eastern asperity 4–15 km deep in Mesozoic carbonates and basement rocks (maximum slip 0.7 m) and a deeper western one (7–16 km depth) mainly in the basement (slip peak 0.8 m). On‐fault aftershocks were concentrated within the basement and Mesozoic carbonates, devoiding high‐slip zones. Slip and aftershock distribution was controlled by the rheological transition between Mesozoic carbonates and Cenozoic sediments. Unlike previous thin‐skinned tectonic interpretations, our results point to a complex rupture process along moderately dipping (40°–45°) thrust‐ramps deeply rooted into the Paleozoic crystalline basement. Plain Language Summary: The two M6 mainshocks of the 2012 Italy sequence are the strongest earthquakes ever observed in the Po Plain, a strategic region for the Italian economy. The mainshocks ruptured blind thrust‐faults, however their source models and seismotectonic interpretation are still debated because the thrust‐system architecture is controversial. Contrasting thick‐skinned and thin‐skinned tectonic models are proposed. In thick‐skinned interpretations, shortening is accommodated by thrust‐ramps rooted into the crystalline basement that represent main seismogenic structures, whereas in thin‐skinned interpretations, shortening and seismicity are controlled by listric faults splaying out from dècollement levels in the sedimentary crust. A comprehensive analysis of the mainshocks' source represents an opportunity to provide new insights into the seismogenesis in northern Italy and on a broader scale into seismotectonics of thrust‐and‐fold belts. We get a complete picture of the mainshocks kinematics by jointly inverting, for the first time, seismic and geodetic data, and unravel rupture heterogeneities not resolved by previous studies. By integrating source models with aftershock locations and geological models, we propose a comprehensive seismotectonic interpretation of the sequence. We conclusively identify the ruptured faults that correspond to thrust‐ramps rooted into the crystalline basement and evidence the key role played by lithological changes in the rupture process. Key Points: Rupture models of the 2012 northern Italy mainshocks obtained by inverting the most comprehensive geodetic and strong motion data set to dateBoth mainshocks ruptured two asperities along moderately dipping thrusts rooted into the Paleozoic crystalline basement down to ∼15 km depthAsperities located in Mesozoic carbonates and Paleozoic basement and slip distribution controlled by lithological and structural barriers [ABSTRACT FROM AUTHOR]

Published

2023

17. From Seismic Monitoring to Tsunami Warning in the Mediterranean Sea

Author

Stefano Lorito, Stefano Pintore, Maria Concetta Lorenzino, Alessio Piatanesi, Fabrizio Bernardi, Salvatore Stramondo, Laura Graziani, Beatriz Brizuela, Jacopo Selva, Manuela Volpe, Francesco Mariano Mele, Roberto Basili, Fabrizio Romano, Roberto Tonini, Alberto Michelini, Antonio Avallone, André Herrero, Alessandro Amato, Amato, Alessandro, Avallone, Antonio, Basili, Roberto, Bernardi, Fabrizio, Brizuela, Beatriz, Graziani, Laura, Herrero, Andr('(e)), Concetta Lorenzino, Maria, Lorito, Stefano, Mariano Mele, Francesco, Michelini, Alberto, Piatanesi, Alessio, Pintore, Stefano, Romano, Fabrizio, Selva, Jacopo, Stramondo, Salvatore, Tonini, Roberto, and Volpe, Manuela

Subjects

Geophysics, Oceanography, Mediterranean sea, 010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences

Abstract

The Italian Tsunami Alert Center based at the Istituto Nazionale di Geofisica e Vulcanologia (CAT-INGV) has been monitoring the Mediterranean seismicity in the past 8 yr to get fast and reliable information for seismically induced tsunami warnings. CAT-INGV is a tsunami service provider in charge of monitoring the seismicity of the Mediterranean Sea and of alerting Intergovernmental Oceanographic Commission (IOC)/UNESCO subscriber Member States and the Italian Department of Civil Protection of a potentially impending tsunami, in the framework of the Tsunami Warning and Mitigation System in the North-eastern Atlantic, the Mediterranean and connected seas (NEAMTWS). CAT-INGV started operating in 2013 and became operational in October 2016. Here, after describing the NEAMTWS in the framework of the global effort coordinated by IOC/UNESCO, we focus on the tsunami hazard in the Mediterranean Sea. We then describe CAT-INGV mandate, functioning, and operational procedures. Furthermore, the article discusses the lessons learned from past events occurring in the Mediterranean Sea, such as the Kos-Bodrum in 2017 (Mw 6.6) and the Samos-Izmir in 2020 (Mw 7.0) earthquakes, which generated moderately damaging tsunamis. Based on these lessons, we discuss some potential improvements for the CAT-INGV and the NEAMTWS, including better seismic and sea level instrumental coverage. We emphasize the need for tsunami risk awareness raising, better preparation, and full implementation of the tsunami warning “last-mile” to foster the creation of a more integrated, interoperable, and sustainable risk reduction framework. If we aim to be better prepared for the next tsunami, these important challenges should be prioritized in the agenda of the IOC/UNESCO Member States and the European Commission.

Published

2021

18. Tsunami Source of the 2021 MW 8.1 Raoul Island Earthquake From DART and Tide-Gauge Data Inversion

Author

William Power, Aditya Riadi Gusman, Stefano Lorito, Manuela Volpe, Alessio Piatanesi, Antonio Scala, Fabrizio Romano, Romano, F., Gusman, A. R., Power, W., Piatanesi, A., Volpe, M., Scala, A., and Lorito, S.

Subjects

Dart, Subduction, warning, Inversion (geology), Kermadec, inversion, Geophysics, General Earth and Planetary Sciences, Tide gauge, DART, tsunami, Bottom pressure, computer, subduction, Geology, Seismology, computer.programming_language

Abstract

The tsunami source of the 2021 MW 8.1 Raoul Island earthquake in the Kermadec subduction zone was estimated by inverting the tsunami signals recorded by Deep-ocean Assessment and Reporting of Tsunamis (DART) bottom pressure sensors and coastal tide-gauges. The main asperity of up to 5 m of slip is located northeastward from the hypocenter, with features compatible with the aftershock distribution and rapid back-projection analysis. Three earthquakes of MW ∼8 or larger which also produced moderate tsunamis happened in the 20th century in the same portion of the subduction zone. This is the first great tsunamigenic event captured by the new New Zealand DART network in the South West Pacific, which proved valuable to estimate a robust image of the tsunami source. We also show a first proof of concept of the capability of this network to reduce the uncertainty associated with tsunami forecasting and to increase the lead time available for evacuation for future alerts.

Published

2021

19. Simulation of tsunamis induced by volcanic activity in the Gulf of Naples (Italy)

Author

S. Tinti, G. Pagnoni, and A. Piatanesi

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

The paper explores the potential of tsunami generation by pyroclastic flows travelling down the flank of the volcano Vesuvius that is found south of Naples in Italy. The eruption history of Vesuvius shows that it is characterised by large explosive eruptions of plinian or subplinian type during which large volume of pyroclastic flows can be produced. The most remarkable examples of such eruptions occurred in 79 AD and in 1631 and were catastrophic. Presently Vesuvius is in a repose time that, according to volcanologists, could be interrupted by a large eruption, and consequently proper plans of preparedness and emergency management have been devised by civil authorities based on a scenario envisaging a large eruption. Recently, numerical models of magma ascent and of eruptive column formation and collapse have been published for the Vesuvius volcano, and propagation of pyroclastic flows down the slope of the volcanic edifice up to the close shoreline have been computed. These flows can reach the sea in the Gulf of Naples: the denser slow part will enter the waters, while the lighter and faster part of the flow can travel on the water surface exerting a pressure on it. This paper studies the tsunami produced by the pressure pulse associated with the transit of the low-density phase of the pyroclastic flow on the sea surface by means of numerical simulations. The study is divided into two parts. First the hydrodynamic characteristics of the Gulf of Naples as regards the propagation of long waves are analysed by studying the waves radiating from a source that is a static initial depression of the sea level localised within the gulf. Then the tsunami produced by a pressure pulse moving from the Vesuvius toward the open sea is simulated: the forcing pulse features are derived from the recent studies on Vesuvian pyroclastic flows in the literature. The tsunami resulting from the computations is a perturbation involving the whole Gulf of Naples, but it is negligible outside, and persists within the gulf long after the transit of the excitation pulse. The size of the tsunami is modest. The largest calculated oscillations are found along the innermost coasts of the gulf at Naples and at Castellammare. The main conclusion of the study is that the light component of the pyroclastic flows produced by future large eruptions of Vesuvius are not expected to set up catastrophic tsunamis.

Published

2003

20. Chapter 7 Scaling of Slip Weakening Distance with Final Slip during Dynamic Earthquake Rupture

Author

Cocco, Massimo, Tinti, Elisa, Marone, Chris, and Piatanesi, Alessio

Published

2009

21. Tsunami waveform inversion by numerical finite-elements Green’s functions

Author

A. Piatanesi, S. Tinti, and G. Pagnoni

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

During the last few years, the steady increase in the quantity and quality of the data concerning tsunamis has led to an increasing interest in the inversion problem for tsunami data. This work addresses the usually ill-posed problem of the hydrodynamical inversion of tsunami tide-gage records to infer the initial sea perturbation. We use an inversion method for which the data space consists of a given number of waveforms and the model parameter space is represented by the values of the initial water elevation field at a given number of points. The forward model, i.e. the calculation of the synthetic tide-gage records from an initial water elevation field, is based on the linear shallow water equations and is simply solved by applying the appropriate Green’s functions to the known initial state. The inversion of tide-gage records to determine the initial state results in the least square inversion of a rectangular system of linear equations. When the inversions are unconstrained, we found that in order to attain good results, the dimension of the data space has to be much larger than that of the model space parameter. We also show that a large number of waveforms is not sufficient to ensure a good inversion if the corresponding stations do not have a good azimuthal coverage with respect to source directivity. To improve the inversions we use the available a priori information on the source, generally coming from the inversion of seismological data. In this paper we show how to implement very common information about a tsunamigenic seismic source, i.e. the earthquake source region, as a set of spatial constraints. The results are very satisfactory, since even a rough localisation of the source enables us to invert correctly the initial elevation field.

Published

2001

22. Scenarios of Earthquake-Generated Tsunamis for the Italian Coast of the Adriatic Sea

Author

Tiberti, Mara Monica, Lorito, Stefano, Basili, Roberto, Kastelic, Vanja, Piatanesi, Alessio, and Valensise, Gianluca

Published

2008

23. Benchmarking the Optimal Time Alignment of Tsunami Waveforms in Nonlinear Joint Inversions for the Mw 8.8 2010 Maule (Chile) Earthquake

Author

Roberto Tonini, Stefano Lorito, Alessio Piatanesi, Thorne Lay, Manuela Volpe, Shane Murphy, and Fabrizio Romano

Subjects

010504 meteorology & atmospheric sciences, business.industry, Geodetic datum, Inversion (meteorology), joint inversion, 010502 geochemistry & geophysics, Geodesy, 01 natural sciences, Seafloor spreading, The 2010 Maule earthquake, benchmark, Epicenter, Trench, Interferometric synthetic aperture radar, Global Positioning System, General Earth and Planetary Sciences, Waveform, optimal time alignment, lcsh:Q, 14. Life underwater, tsunami, business, lcsh:Science, 0105 earth and related environmental sciences

Abstract

Finite-fault models for the 2010Mw8.8 Maule, Chile earthquake indicate bilateral rupture with large-slip patches located north and south of the epicenter. Previous studies also show that this event features significant slip in the shallow part of the megathrust, which is revealed through correction of the forward tsunami modeling scheme used in tsunami inversions. The presence of shallow slip is consistent with the coseismic seafloor deformation measured off the Maule region adjacent to the trench and confirms that tsunami observations are particularly important for constraining far-offshore slip. Here, we benchmark the method of Optimal Time Alignment (OTA) of the tsunami waveforms in the joint inversion of tsunami (DART and tide-gauges) and geodetic (GPS, InSAR, land-leveling) observations for this event. We test the application of OTA to the tsunami Green’s functions used in a previous inversion. Through a suite of synthetic tests we show that if the bias in the forward model is comprised only of delays in the tsunami signals, the OTA can correct them precisely, independently of the sensors (DART or coastal tide-gauges) and, to the first-order, of the bathymetric model used. The same suite of experiments is repeated for the real case of the 2010 Maule earthquake where, despite the results of the synthetic tests, DARTs are shown to outperform tide-gauges. This gives an indication of the relative weights to be assigned when jointly inverting the two types of data. Moreover, we show that using OTA is preferable to subjectively correcting possible time mismatch of the tsunami waveforms. The results for the source model of the Maule earthquake show that using just the first-order modeling correction introduced by OTA confirms the bilateral rupture pattern around the epicenter, and, most importantly, shifts the inferred northern patch of slip to a shallower position consistent with the slip models obtained by applying more complex physics-based corrections to the tsunami waveforms. This is confirmed by a slip model refined by inverting geodetic and tsunami data complemented with a denser distribution of GPS data nearby the source area. The models obtained with the OTA method are finally benchmarked against the observed seafloor deformation off the Maule region. We find that all of the models using the OTA well predict this offshore coseismic deformation, thus overall, this benchmarking of the OTA method can be considered successful.

Published

2020

24. Effects of transient water mass redistribution associated with a tsunami wave on Earths pole path

Author

G. Soldati, A. Piatanesi, D. Melini, A. Piersanti, and A. R. Pisani

Subjects

Earth rotation, pole path variation, tsunami wave, Sumatra earthquake, Meteorology. Climatology, QC851-999, Geophysics. Cosmic physics, QC801-809

Abstract

We have quantified the effects of a water mass redistribution associated with the propagation of a tsunami wave on the Earths pole path and on the Length-Of-Day (LOD) and applied our modeling results to the tsunami following the 2004 giant Sumatra earthquake. We compared the result of our simulations on the instantaneous rotational axis variations with the preliminary instrumental evidence on the pole path perturbation (which has not been confirmed) registered just after the occurrence of the earthquake. The detected perturbation in the pole path showed a step-like discontinuity that cannot be attributed to the effect of a seismic dislocation. Our results show that the tsunami induced instantaneous rotational pole perturbation is indeed characterized by a step-like discontinuity compatible with the observations but its magnitude is almost one hundred times smaller than the detected one. The LOD variation induced by the water mass redistribution turns out to be not significant because the total effect is smaller than current measurements uncertainties.

Published

2007

25. The October 4, 1994 Shikotan (Kurile Islands) Tsunamigenic Earthquake: An Open Problem on the Source Mechanism

Author

Piatanesi, A., Heinrich, P., and Tinti, S.

Published

1999

26. Tsunamigenic earthquake simulations using experimentally derived friction laws

Author

Elena Spagnuolo, Gaetano Festa, A. Scala, Fabrizio Romano, Stefano Aretusini, Shane Murphy, Stefano Lorito, G. Di Toro, Stefan Nielsen, Alessio Piatanesi, Murphy, S., Di Toro, G., Romano, F., Scala, A., Lorito, S., Spagnuolo, E., Aretusini, S., Festa, G., Piatanesi, A., and Nielsen, S.

Subjects

010504 meteorology & atmospheric sciences, Thrust, Slip (materials science), 010502 geochemistry & geophysics, 01 natural sciences, dynamic rupture, megathrust, rock physics experiments, subduction zone, tsunami earthquake, Geophysics, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Space and Planetary Science, Earthquake rupture, Tsunami earthquake, Geophysic, 0105 earth and related environmental sciences, Subduction, Geodetic datum, Tectonics, Law, Geology, rock physics experiment, Asperity (materials science)

Abstract

Seismological, tsunami and geodetic observations have shown that subduction zones are complex systems where the properties of earthquake rupture vary with depth as a result of different pre-stress and frictional conditions. A wealth of earthquakes of different sizes and different source features (e.g. rupture duration) can be generated in subduction zones, including tsunami earthquakes, some of which can produce extreme tsunamigenic events. Here, we offer a geological perspective principally accounting for depth-dependent frictional conditions, while adopting a simplified distribution of on-fault tectonic pre-stress. We combine a lithology-controlled, depth-dependent experimental friction law with 2D elastodynamic rupture simulations for a Tohoku-like subduction zone cross-section. Subduction zone fault rocks are dominantly incohesive and clay-rich near the surface, transitioning to cohesive and more crystalline at depth. By randomly shifting along fault dip the location of the high shear stress regions (“asperities”), moderate to great thrust earthquakes and tsunami earthquakes are produced that are quite consistent with seismological, geodetic, and tsunami observations. As an effect of depth-dependent friction in our model, slip is confined to the high stress asperity at depth; near the surface rupture is impeded by the rock-clay transition constraining slip to the clay-rich layer. However, when the high stress asperity is located in the clay-to-crystalline rock transition, great thrust earthquakes can be generated similar to the Mw 9 Tohoku (2011) earthquake.

Published

2018

27. The 2018 Mw 6.8 Zakynthos (Ionian Sea, Greece) earthquake: Seismic source and local tsunami characterization

Author

Cirella, A. Romano, F. Avallone, A. Piatanesi, A. Briole, P. Ganas, A. Theodoulidis, N. Chousianitis, K. Volpe, M. Bozionellos, G. Selvaggi, G. Lorito, S.

Abstract

We investigated the kinematic rupture model of the 2018 Mw 6.8 Zakynthos, Ionian Sea (Greece), earthquake by using a non-linear joint inversion of strong motion data, high-rate GPS time-series and static coseismic GPS displacements. We also tested inversion results against tide-gauge recordings of the small tsunami generated in the Ionian Sea. In order to constrain the fault geometry, we performed several preliminary kinematic inversions by assuming the parameter values resulting from different published moment tensor solutions. The lowest cost function valueswere obtained by using the geometry derived from theUnited StatesGeological Survey (USGS) focal solution. Between the two conjugate USGS planes, the rupture model which better fits the data is the one with the N9°E-striking 39°ESE-dipping plane. The rupture history of thismodel is characterized by a bilateral propagation, featuring two asperities; amain slip patch extending between 14 and 28 km in depth, 9 km northeast from the nucleation and a slightly shallower small patch located 27 km southwest from the nucleation. The maximum energy release occurs between 8 and 12 s, when both patches are breaking simultaneously. The maximum slip is 1.8 m and the total seismic moment is 2.4 × 1019 Nm, corresponding to a Mw value of 6.8. The slip angle shows a dominant right-lateral strike-slip mechanism, with a minor reverse component that increases on the deeper region of the fault. This result, in addition to the observed possibility of similar mechanisms for previous earthquakes occurred in 1959 and 1997, suggests that the tectonic deformation between the Cephalonia Transform Fault Zone and the northern tip of the Hellenic Arc Subduction zone may be accommodated by prevailing right lateral low-dipping faults, occurring on re-activated structures previously experiencing (until Pliocene) compressional regime. Comparison of predicted and observed tsunami data suggests the need of a better characterization of local harbour response for this type of relatively short-wavelength events, which is important in the context of tsunami early warning. However, the suggested dominantly strike-slip character would in turn imply a reduced tsunami hazard as compared to a dominant thrust faulting regime from this source region. © The Author(s) 2020. Published by Oxford University Press on behalf of The Royal Astronomical Society.

Published

2020

28. Characterization of fault plane and coseismic slip for the 2 May 2020, Mw 6.6 Cretan Passage earthquake from tide gauge tsunami data and moment tensor solutions.

Author

Baglione, Enrico, Lorito, Stefano, Piatanesi, Alessio, Romano, Fabrizio, Basili, Roberto, Brizuela, Beatriz, Tonini, Roberto, Volpe, Manuela, Bayraktar, Hafize Basak, and Amato, Alessandro

Subjects

TSUNAMI warning systems, TSUNAMIS, EARTHQUAKES, TSUNAMI forecasting, SUBDUCTION zones, GAGES, RISK assessment

Abstract

We present a source solution for the tsunami generated by the Mw 6.6 earthquake that occurred on 2 May 2020, about 80 km offshore south of Crete, in the Cretan Passage, on the shallow portion of the Hellenic Arc subduction zone (HASZ). The tide gauges recorded this local tsunami on the southern coast of Crete and Kasos island. We used Crete tsunami observations to constrain the geometry and orientation of the causative fault, the rupture mechanism, and the slip amount. We first modelled an ensemble of synthetic tsunami waveforms at the tide gauge locations, produced for a range of earthquake parameter values as constrained by some of the available moment tensor solutions. We allow for both a splay and a back-thrust fault, corresponding to the two nodal planes of the moment tensor solution. We then measured the misfit between the synthetic and the Ierapetra observed marigram for each source parameter set. Our results identify the shallow, steeply dipping back-thrust fault as the one producing the lowest misfit to the tsunami data. However, a rupture on a lower angle fault, possibly a splay fault, with a sinistral component due to the oblique convergence on this segment of the HASZ, cannot be completely ruled out. This earthquake reminds us that the uncertainty regarding potential earthquake mechanisms at a specific location remains quite significant. In this case, for example, it is not possible to anticipate if the next event will be one occurring on the subduction interface, on a splay fault, or on a back-thrust, which seems the most likely for the event under investigation. This circumstance bears important consequences because back-thrust and splay faults might enhance the tsunamigenic potential with respect to the subduction interface due to their steeper dip. Then, these results are relevant for tsunami forecasting in the framework of both the long-term hazard assessment and the early warning systems. [ABSTRACT FROM AUTHOR]

Published

2021

29. Tsunamigenic earthquake simulations using experimentally derived friction laws

Author

Murphy, S., Di Toro, G., Romano, F., Scala, A., Lorito, S., Spagnuolo, E., Aretusini, S., Festa, G., Piatanesi, A., and Nielsen, S.

Published

2018

30. Sensitivity of Tsunami Scenarios to Complex Fault Geometry and Heterogeneous Slip Distribution: Case‐Studies for SW Iberia and NW Morocco.

Author

Serra, C. S., Martínez‐Loriente, S., Gràcia, E., Urgeles, R., Gómez de la Peña, L., Maesano, F. E., Basili, R., Volpe, M., Romano, F., Scala, A., Piatanesi, A., and Lorito, S.

Subjects

SEISMIC waves, SEISMOLOGY, EARTH movements, EARTHQUAKES, FAULT zones

Abstract

The SW Iberian margin is one of the most seismogenic and tsunamigenic areas in W‐Europe, where large historical and instrumental destructive events occurred. To evaluate the sensitivity of the tsunami impact on the coast of SW Iberia and NW Morocco to the fault geometry and slip distribution for local earthquakes, we carried out a set of tsunami simulations considering some of the main known active crustal faults in the region: the Gorringe Bank (GBF), Marquês de Pombal (MPF), Horseshoe (HF), North Coral Patch (NCPF) and South Coral Patch (SCPF) thrust faults, and the Lineament South strike‐slip fault. We started by considering for all of them relatively simple planar faults featuring with uniform slip distribution; we then used a more complex 3D fault geometry for the faults constrained with a large 2D multichannel seismic dataset (MPF, HF, NCPF, and SCPF); and finally, we used various heterogeneous slip distributions for the HF. Our results show that using more complex 3D fault geometries and slip distributions, the peak wave height at the coastline can double compared to simpler tsunami source scenarios from planar fault geometries. Existing tsunami hazard models in the region use homogeneous slip distributions on planar faults as initial conditions for tsunami simulations and therefore underestimate tsunami hazard. Complex 3D fault geometries and non‐uniform slip distribution should be considered in future tsunami hazard updates. The tsunami simulations also support the finding that submarine canyons attenuate the wave height reaching the coastline, while submarine ridges and shallow shelves have the opposite effect. Plain Language Summary: Deformation along the present‐day plate boundary between Africa and Eurasia off SW Iberia is distributed over a 200‐km‐wide and 600‐km‐long area, and is mainly accommodated by thrusts and strike‐slip faults. The region hosts frequent seismic activity of moderate magnitude punctuated by higher magnitude events, which have also originated major historical and pre‐historical tsunamis. The run‐up and coastal area affected by these tsunamis depend on the characteristics and location of the seismic source, bathymetry, and morphology of the coasts. Previous tsunami hazard assessments in the region used simplified fault models for tsunami simulations, ignoring the detailed 3D fault geometry and slip distribution. To investigate the sensitivity of the tsunami impact and eventually of the hazard to these complexities, we have carried out a series of tsunami simulations using planar and 3D fault surfaces, as well as homogeneous and heterogeneous slips. To build the fault surfaces, we used a large dataset of 2D multichannel seismic profiles that images the active faults in the region. Our study indicates that using the more complex fault models produce significantly larger tsunamis with the modeled wave heights at the coastline that can be several times bigger than those generated using planar fault sources. Key Points: The tsunami is sensitive to both the fault geometry and the slip distributionIntroducing complexity into the fault geometry and slip distribution can strongly enhance the simulated wave height at the coastOversimplified source models may hinder the prediction of the tsunami intensity, hence the tsunami hazard analysis [ABSTRACT FROM AUTHOR]

Published

2021

31. Tsunami Source of the 2021 MW 8.1 Raoul Island Earthquake From DART and Tide‐Gauge Data Inversion.

Author

Romano, F., Gusman, A. R., Power, W., Piatanesi, A., Volpe, M., Scala, A., and Lorito, S.

Subjects

TSUNAMI warning systems, TSUNAMIS, TSUNAMI forecasting, EARTHQUAKES, SUBDUCTION zones, PRESSURE sensors, LEAD time (Supply chain management)

Abstract

The tsunami source of the 2021 MW 8.1 Raoul Island earthquake in the Kermadec subduction zone was estimated by inverting the tsunami signals recorded by Deep‐ocean Assessment and Reporting of Tsunamis (DART) bottom pressure sensors and coastal tide‐gauges. The main asperity of up to 5 m of slip is located northeastward from the hypocenter, with features compatible with the aftershock distribution and rapid back‐projection analysis. Three earthquakes of MW ∼8 or larger which also produced moderate tsunamis happened in the 20th century in the same portion of the subduction zone. This is the first great tsunamigenic event captured by the new New Zealand DART network in the South West Pacific, which proved valuable to estimate a robust image of the tsunami source. We also show a first proof of concept of the capability of this network to reduce the uncertainty associated with tsunami forecasting and to increase the lead time available for evacuation for future alerts. Plain Language Summary: We estimated the tsunami source for the 4 March 2021 Raoul Island earthquake (MW 8.1), obtained by inverting tsunami data from tide‐gauges and open ocean Deep‐ocean Assessment and Reporting of Tsunamis (DART) stations. The main asperity of up to 5 m of slip is located northeastward from the hypocenter, with features compatible with the aftershock distribution and rapid back‐projection analysis. This event is important because it was the strongest one of three earthquakes that occurred within hours during the same day. Moreover, it caused the largest of three tsunami that altogether represent a great test for the New Zealand DART new network. The results demonstrate the potential importance of this new DART network for resolving the tsunami source and for early warning purposes as it can reduce the uncertainty of the tsunami forecasts and at the same time increase the lead time available for evacuation. Key Points: Tsunami source of the 2021 MW 8.1 Raoul Island earthquake by inverting tsunami waveformsThe main slip peaks at 5 m and is located at a depth of ∼20–30 and ∼100 km north of the epicenterNew Deep‐ocean Assessment and Reporting of Tsunamis network was crucial for characterizing the source and will significantly reduce the uncertainty and speed up future warnings [ABSTRACT FROM AUTHOR]

Published

2021

32. An Analysis about reverse offshoring

Author

Arauzo Carod, Josep Maria, Piatanesi, Benedetta, and Universitat Rovira i Virgili. Departament d'Economia

Subjects

332 - Economia regional i territorial. Economia del sòl i de la vivenda, Economia regional, Localització industrial

Abstract

Economies that traditionally benefited from offshoring are losing some of their strategical advantages, with a consequent increase in backshoring (i.e., reverse offshoring) by developed economies. This paper describes this phenomenon and tries to shed light, from an Italian perspective, on the current challenges, trends and debates of backshoring, and on its main determinants. A new phenomenon known as nearshoring is also analysed—this consists of relocating some previously offshored manufacturing activities so that they are now close to previous core locations, but not so close as to suffer from disagglomeration effects. Key words: offshoring, backshoring, and nearshoring. JEL Classification: R12, R30

Published

2019

33. A finite-element numerical approach for modeling tsunamis

Author

A. Piatanesi, I. Gavagni, and S. Tinti

Subjects

Analytical tests, boundary conditions, finite-element, numerical model, shallows-water approximation, tsunami, Meteorology. Climatology, QC851-999, Geophysics. Cosmic physics, QC801-809

Abstract

A numerical scheme suitable for modeling tsunamis is developed and tested against available analytical solutions. The governing equations are the shallow water nonlinear nondispersive equations that are known to be appropriate for tsunami generation and propagation in coastal waters. The integration scheme is based on a finite-element space discretization, where the basic elements are triangles and the shape functions are linear. The time integration is a double step algorithm that is accurate to the second order in the time step ?t. The boundary conditions are pure reflectivity and complete transmissivity on the solid and open boundaries respectively and are implemented by modifying the time integration scheme in a suitable way. The model performance is evaluated by comparing the results with the analytical solutions in selected cases and is quite satisfactory, even when the grid has a coarse spatial resolution.

Published

1994

34. Source of the 6 February 2013 Mw = 8.0 Santa Cruz Islands Tsunami

Author

F. Romano, I. Molinari, S. Lorito, and A. Piatanesi

Subjects

lcsh:GE1-350, lcsh:Geology, lcsh:G, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, lcsh:Environmental technology. Sanitary engineering, lcsh:TD1-1066, lcsh:Environmental sciences

Abstract

On 6 February 2013 an Mw = 8.0 subduction earthquake occurred close to Santa Cruz Islands at the transition between the Solomon and the New Hebrides Trench. The ensuing tsunami caused significant inundation on the closest Nendo Island. The seismic source was studied with teleseismic broadband P-wave inversion optimized with tsunami forward modelling at DART buoys (Lay et al., 2013) and with inversion of teleseismic body and surface waves (Hayes et al., 2014a). The two studies also use different hypocentres and different planar fault models and found quite different slip models. In particular, Hayes et al. (2014a) argued for an aseismic slip patch SE from the hypocentre. We here develop a 3-D model of the fault surface from seismicity analysis and retrieve the tsunami source by inverting DART and tide-gauge data. Our tsunami source model features a main slip patch (peak value of ~ 11 m) SE of the hypocentre and reaching the trench. The rake direction is consistent with the progressively more oblique plate convergence towards the Solomon trench. The tsunami source partially overlaps the hypothesized aseismic slip area, which then might have slipped coseismically.

Published

2018

35. Characterisation of fault plane and coseismic slip for the May 2, 2020, Mw 6.6 Cretan Passage earthquake from tide-gauge tsunami data and moment tensor solutions.

Author

Baglione, Enrico, Lorito, Stefano, Piatanesi, Alessio, Romano, Fabrizio, Basili, Roberto, Brizuela, Beatriz, Tonini, Roberto, Volpe, Manuela, Basak Bayraktar, Hafize, and Amato, Alessandro

Subjects

TSUNAMI warning systems, TSUNAMIS, EARTHQUAKES, TSUNAMI forecasting, SUBDUCTION zones, RISK assessment, SUBDUCTION

Abstract

We present a source solution for the tsunami generated by the Mw 6.6 earthquake that occurred on May 2, 2020, about 807 km offshore south of Crete, in the Cretan Passage, on the shallow portion of the Hellenic Arc Subduction Zone (HASZ). The tide-gauges recorded this local tsunami on the southern coast of Crete island and Kasos island. We used these tsunami observations to constrain the geometry and orientation of the causative fault, the rupture mechanism and the slip amount. We first modelled an ensemble of synthetic tsunami waveforms at the tide-gauge locations, produced for a range of earthquake parameter values as constrained by some of the available moment tensor solutions. We allow for both a splay and a back-thrust fault, corresponding to the two nodal planes of the moment tensor solution. We then measured the misfit between the synthetic and the observed marigrams for each source parameter set. Our results identify the shallow steeply-dipping back-thrust fault as the one producing the lowest misfit to the tsunami data. However, a rupture on a lower angle fault, possibly a splay fault, with a sinistral component due to the oblique convergence on this segment of the HASZ, cannot be completely ruled out. This earthquake reminds us that the uncertainty regarding potential earthquake mechanisms at a specific location remains quite significant. In this case, for example, it is not possible to anticipate if the next event will be one occurring on the subduction interface, on a splay fault, or on a back-thrust which seems the most likely for the event under investigation. This circumstance bears important consequences because back-thrust and splay faults might enhance the tsunamigenic potential with respect to the subduction interface due to their steeper dip. Then, these results are relevant for tsunami forecasting both in the framework of the long-term hazard assessment and of the early warning systems. [ABSTRACT FROM AUTHOR]

Published

2021

36. Near-source high-rate GPS, strong motion and InSAR observations to image the 2015 Lefkada (Greece) Earthquake rupture history

Author

Cristiano Tolomei, Antonella Cirella, Nikos Theodoulidis, Athanassios Ganas, Pierre Briole, Alessio Piatanesi, Daniele Cheloni, Antonio Avallone, Institut de Physique du Globe de Paris (IPGP), Institut national des sciences de l'Univers (INSU - CNRS)-IPG PARIS-Université Paris Diderot - Paris 7 (UPD7)-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS), Institute of Engineering Seismology and Earthquake Engineering (ITSAK), Laboratoire de géologie de l'ENS (LGENS), Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Département des Géosciences - ENS Paris, École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), National Observatory of Athens (NOA), Centre National de la Recherche Scientifique (CNRS)-Université de La Réunion (UR)-Université Paris Diderot - Paris 7 (UPD7)-IPG PARIS-Institut national des sciences de l'Univers (INSU - CNRS), Laboratoire de géologie de l'ENS (LGE), and École normale supérieure - Paris (ENS Paris)-École normale supérieure - Paris (ENS Paris)

Subjects

[SDU.STU.TE]Sciences of the Universe [physics]/Earth Sciences/Tectonics, Multidisciplinary, 010504 meteorology & atmospheric sciences, Science, Rake, Transform fault, Slip (materials science), 010502 geochemistry & geophysics, Geodesy, 01 natural sciences, Article, Tectonics, Rise time, Interferometric synthetic aperture radar, Seismic moment, Medicine, Earthquake rupture, ComputingMilieux_MISCELLANEOUS, Geology, 0105 earth and related environmental sciences

Abstract

The 2015/11/17 Lefkada (Greece) earthquake ruptured a segment of the Cephalonia Transform Fault (CTF) where probably the penultimate major event was in 1948. Using near-source strong motion and high sampling rate GPS data and Sentinel-1A SAR images on two tracks, we performed the inversion for the geometry, slip distribution and rupture history of the causative fault with a three-step self-consistent procedure, in which every step provided input parameters for the next one. Our preferred model results in a ~70° ESE-dipping and ~13° N-striking fault plane, with a strike-slip mechanism (rake ~169°) in agreement with the CTF tectonic regime. This model shows a bilateral propagation spanning ~9 s with the activation of three main slip patches, characterized by rise time and peak slip velocity in the ranges 2.5–3.5 s and 1.4–2.4 m/s, respectively, corresponding to 1.2–1.8 m of slip which is mainly concentrated in the shallower (0 = 1.05 × 1019 N m) suggest a magnitude of M w 6.6. Our best solution suggests that the occurrence of large (M w > 6) earthquakes to the northern and to the southern boundaries of the 2015 causative fault cannot be excluded.

Published

2017

37. Quantification of source uncertainties in Seismic Probabilistic Tsunami Hazard Analysis (SPTHA)

Author

Alessio Piatanesi, Anita Grezio, Irene Molinari, Roberto Basili, Jacopo Selva, Stefano Lorito, Fabrizio Romano, Mara Monica Tiberti, Daniele Melini, Roberto Tonini, Selva, J., Tonini, R., Molinari, I., Tiberti, M. M., Romano, F., Grezio, A., Melini, D., Piatanesi, A., Basili, R., and Lorito, S.

Subjects

Earthquake interaction, forecasting, and prediction, 010504 meteorology & atmospheric sciences, Probabilistic forecasting, Probabilistic logic, 010502 geochemistry & geophysics, 01 natural sciences, Europe, Geophysics, Geochemistry and Petrology, Tsunami hazard, Tsunamis, Seismology, Geology, 0105 earth and related environmental sciences

Abstract

We propose a procedure for uncertainty quantification in Probabilistic Tsunami Hazard Analysis (PTHA), with a special emphasis on the uncertainty related to statistical modelling of the earthquake source in Seismic PTHA (SPTHA), and on the separate treatment of subduction and crustal earthquakes (treated as background seismicity). An event tree approach and ensemble modelling are used in spite of more classical approaches, such as the hazard integral and the logic tree. This procedure consists of four steps: (1) exploration of aleatory uncertainty through an event tree, with alternative implementations for exploring epistemic uncertainty; (2) numerical computation of tsunami generation and propagation up to a given offshore isobath; (3) (optional) site-specific quantification of inundation; (4) simultaneous quantification of aleatory and epistemic uncertainty through ensemble modelling. The proposed procedure is general and independent of the kind of tsunami source considered; however, we implement step 1, the event tree, specifically for SPTHA, focusing on seismic source uncertainty. To exemplify the procedure, we develop a case study considering seismic sources in the Ionian Sea (central-eastern Mediterranean Sea), using the coasts of Southern Italy as a target zone. The results show that an efficient and complete quantification of all the uncertainties is feasible even when treating a large number of potential sources and a large set of alternative model formulations. We also find that (i) treating separately subduction and background (crustal) earthquakes allows for optimal use of available information and for avoiding significant biases; (ii) both subduction interface and crustal faults contribute to the SPTHA, with different proportions that depend on source-target position and tsunami intensity; (iii) the proposed framework allows sensitivity and deaggregation analyses, demonstrating the applicability of the method for operational assessments.

Published

2016

38. Identification of the source fault of the 1908 Messina earthquake through tsunami modelling. Is it a possible task?

Author

Tinti, S., Armigliato, A., Bortolucci, E., and Piatanesi, A.

Published

1999

39. Finite-element simulations of the 28 december 1908 Messina Straits (Southern Italy) tsunami

Author

Piatanesi, A., Tinti, S., and Bortolucci, E.

Published

1999

40. The Global Tsunami Model GTM

Author

KÂNOĞLU, UTKU, Lovholt, Finn, Thio, Hong Kie, Carl, Harbitz, Jascha, Polet, Lorito, Stefano, Basili, Roberta, Volpe, Manuela, Romano, Fabrizio, Selva, Jacopo, Piatanesi, Alessio, Davies, Gareth, Griffin, Jonathan, Baptista, Maria Ana, Omira, Rasid, Babeyko, Andrey, Power, William, Galvez, Mario Salgado, Behrens, Joern, YALÇINER, AHMET CEVDET, and ve, diğerleri

Published

2016

41. Guidelines for stress-test design for non-nuclear critical infrastructures and systems: Applications: STREST Reference Report 5

Author

AKKAR Sinan, ARGYROUDIS Sotiris, BABIČ Anže, BASCO Anna, BASILI Roberto, BRIZUELA Beatriz, CHENG Ying, COURAGE Wim, CROWLEY Helen, DOLŠEK Matjaž, ERDIK Mustafa, ESPOSITO Simona, FOTOPOULOU Stavroula, GIARDINI Domenico, IQBAL Sarfraz, KARAFAGKA Stella, LORITO Stefano, MATOS José Pedro, PIATANESI Alessio, REINDERS Johan, RODRIGUES Daniela, ROMANO Fabrizio, SALZANO Ernesto, SCHLEISS Anton J., SELVA Jacopo, STOJADINOVIĆ Bozidar, TONINI Roberto, UÇKAN Eren, VOLPE Manuela, MIGNAN Arnaud, PITILAKIS Kyriazis, and TSIONIS Georgios

Abstract

In the context of the STREST project, an engineering multi-level risk-based methodology to stress test critical non-nuclear infrastructures, named ST@STREST, has been developed. This reference report summarizes ST@STREST framework and its exploratory application to six key representative Critical Infrastructures (CIs) in Europe, exposed to variant hazards, namely: a petrochemical plant in Milazzo, Italy, large dams of the Valais region in Switzerland, hydrocarbon pipelines in Turkey, the Gasunie national gas storage and distribution network in Holland, the port infrastructure of Thessaloniki, Greece and an industrial district in the region of Tuscany, Italy. According to the characteristics of each case study, different stress test levels were applied. The application to the selected CIs is presented following the workflow of ST@STREST, comprised of four phases: Pre-Assessment phase; Assessment phase; Decision phase; and Report phase. First the goals, the method, the time frame, and the appropriate stress test level to apply are defined. Then, the stress test is performed at component and system levels and the outcomes are checked and compared to the acceptance criteria. A stress test grade is assigned and the global outcome is determined by employing a grading system. Finally, critical events and risk mitigation strategies are formulated and reported to stakeholders and authorities., JRC.E.4-Safety and Security of Buildings

Published

2016

42. Backshoring and nearshoring: An overview.

Author

Piatanesi, Benedetta and Arauzo‐Carod, Josep‐Maria

Subjects

*DEBATE

Abstract

Increasingly, economies that have traditionally benefited from offshoring are losing some of their strategical advantages, with a consequent increase in backshoring by developed economies. This paper describes the phenomenon and tries to shed light on the current challenges, trends, and debates in the area, and on the main determinants of backshoring. A new phenomenon known as nearshoring is also analysed—this consists of relocating some previously offshored manufacturing activities so that they are now close to previous core locations, but not so close as to suffer from disagglomeration effects. This combines the advantages of offshoring and backshoring. [ABSTRACT FROM AUTHOR]

Published

2019

43. Reply to 'Comment on ‘The 28 December 1908 Messina Straits Earthquake (Mw 7.1): A Great Earthquake throughout a Century of Seismology,’ by N. A. Pino, A. Piatanesi, G. Valensise, and E. Boschi' by A. Amoruso, L. Crescentini, and R. Scarpa

Author

Enzo Boschi, Nicola Alessandro Pino, Gianluca Valensise, Alessio Piatanesi, N. A. Pino, A. Piatanesi, G. Valensise, and E. Boschi

Subjects

Geophysics, Seismic moment, Slip (materials science), Maxima, Seismogram, Seismology, Geology

Abstract

This is a rather unusual comment that focuses on how a specific figure was constructed rather than on actual scientific results. The figure in question (Figure 9 from Pino et al. 2009) does not even show new data or results, but is simply a summary of slip models that have been proposed in the literature for the 1908 earthquake. All models describe slip distributions from coseismic elevation changes except for one, derived by Pino et al. (2000) based on waveform modeling of historical seismograms. To construct Figure 9 we simply plotted the slip maxima obtained by different workers in a 2D diagram having the northward distance from a conventional point in the Ionian Sea on the x -axis and slip on the y -axis. The first two sentences of its caption read: “Slip distribution along-strike of the fault resulting from various studies. The diagram consistently shows the maximum slip recorded along each section of the fault.” The distribution reported as “Amoruso et al. (2002)” was based on their Model A (see our Figure 1 and Figure 1B of the comment). Model A exhibits two prominent maxima (respectively a and c in our Figure 1), described as follows in Amoruso et al. (2002): “the majority of the seismic moment is released in a region, ∼ 600 km2 in area, extending south of the Calabrian coastline (the highest slip is ∼ 6 m at a depth of ∼ 6 km); a smaller slip patch is 25 km NE of the Ganzirri peninsula, at a depth of ∼ 17 km.” Amoruso et al. (2010) claim that Figure 9 is “inconsistent and misleading”; they never explicitly say why, but propose an alternative, more subjective way of plotting the same data. We firmly believe our Figure 9 was constructed in a plain and easily …

Published

2010

44. Source of the 6 February 2013 M-w=8.0 Santa Cruz Islands Tsunami

Author

Romano, Fabrizio, Molinari, Irene, Lorito, Stefano, and Piatanesi, Alessio

Abstract

On 6 February 2013 an Mw = 8.0 subduction earthquake occurred close to Santa Cruz Islands at the transition between the Solomon and the New Hebrides Trench. The ensuing tsunami caused significant inundation on the closest Nendo Island. The seismic source was studied with teleseismic broadband P-wave inversion optimized with tsunami forward modelling at DART buoys (Lay et al., 2013) and with inversion of teleseismic body and surface waves (Hayes et al., 2014a). The two studies also use different hypocentres and different planar fault models and found quite different slip models. In particular, Hayes et al. (2014a) argued for an aseismic slip patch SE from the hypocentre. We here develop a 3-D model of the fault surface from seismicity analysis and retrieve the tsunami source by inverting DART and tide-gauge data. Our tsunami source model features a main slip patch (peak value of ~ 11 m) SE of the hypocentre and reaching the trench. The rake direction is consistent with the progressively more oblique plate convergence towards the Solomon trench. The tsunami source partially overlaps the hypothesized aseismic slip area, which then might have slipped coseismically., Natural Hazards and Earth System Sciences, 15 (6), ISSN:1561-8633, ISSN:1684-9981

Published

2015

45. Tsunami waveform inversion by numerical finite-elements Green’s functions

Author

Alessio Piatanesi, Gianluca Pagnoni, and Stefano Tinti

Subjects

lcsh:GE1-350, Mathematical optimization, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, Perturbation (astronomy), Inverse transform sampling, Inversion (meteorology), Geodesy, System of linear equations, Finite element method, lcsh:TD1-1066, lcsh:Geology, lcsh:G, General Earth and Planetary Sciences, Waveform, A priori and a posteriori, lcsh:Environmental technology. Sanitary engineering, Shallow water equations, lcsh:Environmental sciences, Mathematics

Abstract

During the last few years, the steady increase in the quantity and quality of the data concerning tsunamis has led to an increasing interest in the inversion problem for tsunami data. This work addresses the usually ill-posed problem of the hydrodynamical inversion of tsunami tide-gage records to infer the initial sea perturbation. We use an inversion method for which the data space consists of a given number of waveforms and the model parameter space is represented by the values of the initial water elevation field at a given number of points. The forward model, i.e. the calculation of the synthetic tide-gage records from an initial water elevation field, is based on the linear shallow water equations and is simply solved by applying the appropriate Green’s functions to the known initial state. The inversion of tide-gage records to determine the initial state results in the least square inversion of a rectangular system of linear equations. When the inversions are unconstrained, we found that in order to attain good results, the dimension of the data space has to be much larger than that of the model space parameter. We also show that a large number of waveforms is not sufficient to ensure a good inversion if the corresponding stations do not have a good azimuthal coverage with respect to source directivity. To improve the inversions we use the available a priori information on the source, generally coming from the inversion of seismological data. In this paper we show how to implement very common information about a tsunamigenic seismic source, i.e. the earthquake source region, as a set of spatial constraints. The results are very satisfactory, since even a rough localisation of the source enables us to invert correctly the initial elevation field.

Published

2001

46. Source process of the September 12, 2007, Mw 8.4 southern Sumatra earthquake from tsunami tide gauge record inversion

Author

Enzo Boschi, Fabrizio Romano, Stefano Lorito, Alessio Piatanesi, Lorito S., Romano F., Piatanesi A., and Boschi E.

Subjects

Indian ocean, Geophysics, Epicenter, Non linear inversion, General Earth and Planetary Sciences, Tide gauge, Inversion (meteorology), West coast, Geodesy, Far East, Tsunami earthquake, Geology, Seismology

Abstract

[1] We infer the slip distribution and average rupture velocity of the magnitude MW 8.4 September 12, 2007, southern Sumatra earthquake from available tide-gauge records of the ensuing tsunami. We select 9 waveforms recorded along the west coast of Sumatra and in the Indian Ocean. Slip distribution and rupture velocity are determined simultaneously by means of a non linear inversion method. We find high slip values (∼10 m) into a patch 100 km long and 50 km large, between 20 and 30 km of depth, about 100 km north-west from the epicenter. We conclude this earthquake did not rupture the whole area of the 1833 event, indicating some slip has still to occur. Our estimate of rupture velocity is of 2.1 ± 0.4 km/sec. The relatively large depth of the main slip patch is the likely explanation for the low damaging observed tsunami.

Published

2008

47. Complexity of the rupture process during the 2009 L’Aquila, Italy, earthquake

Author

Cirella, A, Piatanesi, A, Tinti, E, and M and Cocco M, Chini

Published

2012

48. Scaling of slip weakening distance with final slip during dynamic earthquake rupture

Author

Cocco, M, Tinti, E, Marone, C, and Piatanesi, A

Published

2009

49. From the 1908 Messina Earthquake to Scenario Damage Assessment in 2008

Author

Teramo, Antonio, Bottari, Antonio, Termini, Domenica, Teramo, M. S., Crowley, H, Pinho, R, Lopez, M, Cultrera, G, Cocco, M, Cirella, A, Herrero, A, Piatanesi, A, Lorito, S, Romano, F, Mai, M, and Salvatore, W.

Subjects

Scenari di danno sismico

Published

2008

50. Near-field propagation of tsunamis from megathrust earthquakes

Author

Alessio Piatanesi, Sandy Steacy, Massimo Cocco, Andrea Antonioli, Süleyman S. Nalbant, John McCloskey, Carlo Giunchi, Kerry Sieh, Jiandong Huang, and Paul Dunlop

Subjects

Wavelength, Geophysics, Subduction, General Earth and Planetary Sciences, Geodetic datum, Near and far field, Slip (materials science), Science::Geology::Volcanoes and earthquakes [DRNTU], Tsunami earthquake, Forearc, Seismology, Seafloor spreading, Geology

Abstract

We investigate controls on tsunami generation and propagation in the near-field of great megathrust earthquakes using a series of numerical simulations of subduction and tsunamigenesis on the Sumatran forearc. The Sunda megathrust here is advanced in its seismic cycle and may be ready for another great earthquake. We calculate the seafloor displacements and tsunami wave heights for about 100 complex earthquake ruptures whose synthesis was informed by reference to geodetic and stress accumulation studies. Remarkably, results show that, for any near-field location: (1) the timing of tsunami inundation is independent of slipdistribution on the earthquake or even of its magnitude, and (2) the maximum wave height is directly proportional to the vertical coseismic displacement experienced at that location. Both observations are explained by the dominance of long wavelength crustal flexure in near-field tsunamigenesis. The results show, for the first time, that a single estimate of vertical coseismic displacement might provide a reliable short-term forecast of the maximum height of tsunami waves. Published version

Published

2007