ALBERT

Description: We investigated the contribution of earthquake-induced surface movements to the ground displacements detected through Interferometric Synthetic Aperture Radar (InSAR) data, after the Mw 3.9 Ischia earthquake on 21 August 2017. A permanent displacement approach, based on the limit equilibrium method, allowed estimation of the spatial extent of the earthquake-induced landslides and the associated probability of failure. The proposed procedure identified critical areas potentially affected by slope movements partially overlapping the coseismic ground displacement retrieved by InSAR data. Therefore, the observed ground displacement field is the combination of both fault slip and surficial sliding caused by the seismic shaking. These findings highlight the need to perform preliminary calculations to account for the non-tectonic contributions to ground displacements before any estimation of the earthquake source geometry and kinematics. Such information is fundamental to avoid both the incorrect definition of the source geometry and the possible overestimation of the coseismic slip over the causative fault. Moreover, knowledge of the areas potentially affected by slope movements could contribute to better management of a seismic emergency, especially in areas exposed to high seismic and hydrogeological risks.

Description: Published

Description: 0303

Description: 2T. Deformazione crostale attiva

Description: JCR Journal

Description: The Gargano Promontory (southern Italy) is an ENE-WSW oriented topographical and structural high, located in the Adriatic foreland between the Apennines and the Dinarides-Albanides fold-and-thrust belts. The stratigraphy of the area is characterized by a succession of Neogene shallow-water rocks (Early Miocene to Late Pliocene age), that unconformably covers the Mesozoic substratum. The entire succession is dissected by a complex and active fault system: the most prominent and the most active evidence of these structures is the Mattinata fault. In general a shared kinematic interpretation of the Gargano structure still does not exist and the debate is still open. In fact, previous works have inferred a reverse, right-lateral, left-lateral or inverted kinematic for the Mattinata fault, while the NW-SE fault system, located north of the Mattinata fault, has been interpreted either as a normal or a reverse fault system. The understanding of the kinematics related to the Gargano area plays an important role for the development of a new geodynamical model of the Appenninic outer deformation front and, ultimately, could provide important insights into the evolution of the Africa-Eurasia plate boundary in the central Mediterranean region. Another central point is that, although the Gargano area is located in the foreland, it is seismically active: the present level of the background seismicity is low (maximum magnitude Mw=5.4 occurring in the central part of the promontory), but destructive earthquakes (and even a tsunami) have occurred in historical times, with felt effects up to XI MCS. We have investigated the surface deformation by InSAR methodology: we have obtained ground motion time series using PS (Permanent Scatter) and SBAS (Small BAseline Subset) processing techniques. Both methods allow us to generate long time series of displacement and to analyse the velocity variation during that time. In the PS technique only the natural targets, showing a good stability of the backscattered signal in all the images, are considered for the calculation of the phase difference between acquisitions. In the SBAS approach, the entire image dataset is split into different subsets, characterized by small temporal and spatial baseline. With regard to the SBAS we have considered both ERS and ENVISAT orbits (93 descending and 47 ascending data) to obtain time series starting from 1992 to 2006. Instead the PS technique has been applied to the Gargano area using 83 ERS1-2 images relative to descending orbit and 31 images from ascending orbit respectively, in the period 1992-2002. We interpret the velocity fields retrieved by SBAS/PS technique in term of interseismic strain accumulation and propose some preliminary model to describe the underlying kinematic mechanism.

Description: Published

Description: Wien, EGU2010-511

Description: 1.10. TTC - Telerilevamento

Description: open

Description: Geological disasters are responsible for the loss of human lives and for significant economic and financial damage every year. Considering that these disasters may occur anywhere—both in remote and/or in highly populated areas—and anytime, continuously monitoring areas known to be more prone to geohazards can help to determine preventive or alert actions to safeguard human life, property and businesses. Remote sensing technology—especially satellite-based—can be of help due to its high spatial and temporal coverage. Indeed, data acquired from the most recent satellite missions is considered suitable for a detailed reconstruction of past events but also to continuously monitor sensitive areas on the lookout for potential geohazards. This work aims to apply different techniques and methods for extensive exploitation and analysis of remote sensing data, with special emphasis given to landslide hazard, risk management and disaster prevention. Multi-temporal SAR (Synthetic Aperture Radar) interferometry, SAR tomography, high-resolution image matching and data modelling are used to map out landslides and other geohazards and to also monitor possible hazardous geological activity, addressing different study areas: (i) surface deformation of mountain slopes and glaciers; (ii) land surface displacement; and (iii) subsidence, landslides and ground fissure. Results from both the processing and analysis of a dataset of earth observation (EO) multi-source data support the conclusion that geohazards can be identified, studied and monitored in an effective way using new techniques applied to multi-source EO data. As future work, the aim is threefold: extend this study to sensitive areas located in different countries; monitor structures that have strategic, cultural and/or economical relevance; and resort to artificial intelligence (AI) techniques to be able to analyse the huge amount of data generated by satellite missions and extract useful information in due course

Description: Published

Description: 4269

Description: 2T. Deformazione crostale attiva

Description: JCR Journal

Description: In this paper, we study the spatial distribution and temporal evolution of the postseismic deformation of the 2010–2011 Rigan earthquake sequence which occurred at the southern termination of the East Lut fault system, southeast Iran. One-year GPS measurements after the Rigan earthquake sequence reveals right-lateral postseismic displacement along the East Chahqanbar fault and left-lateral postseismic displacement along the South Chahqanbar fault. To investigate the deformation variations in time and space, InSAR time-series of COSMO-SkyMed images is applied using the Small Baseline Subset algorithm. The results confirm a clear cumulative postseismic signal increasing to 8 mm during the first five months following the first mainshock in the direction of the coseismic displacement. The cumulative postseismic displacements are well correlated with the cumulative number of the aftershocks and their associated moment release. Considering this correlation and the observation of a sharp discontinuity along the coseismic fault in the displacement map, it is concluded that the after-slip mechanism is responsible for the observed postseismic deformation in the study region. This study is the first observation of a short-term postseismic motion in eastern Iran through geodetic data in contrast with long-lasting postseismic displacements following the earthquakes that occurred around Lut block. Modeling of the postseismic displacement results in a distributed slip pattern with a maximum slip of 0.8 m on the fault plane responsible for the 2010 Rigan coseismic deformation. This indicates that the postseismic deformation on barriers remained unbroken during the mainshock.

Description: Published

Description: 228630

Description: 2T. Deformazione crostale attiva

Description: JCR Journal