Your search keyword '"Pernicana Fault"' showing total 10 results

1. Using a vibratory source at Mt. Etna (Italy) to investigate the wavefield polarization at Pernicana Fault.

Author

Di Giulio, Giuseppe, Punzo, Michele, Bruno, Pier Paolo, Cara, Fabrizio, and Rovelli, Antonio

Subjects

GEOLOGIC faults, VIBRATION (Mechanics), SHEAR waves, VELOCIMETERS

Abstract

The paper presents the results of a controlled‐source seismic experiment performed using a vibratory source capable of producing harmonic vibrations. The survey aimed at investigating the horizontal directional amplification mechanism observed at the Pernicana Fault (Mt. Etna in Sicily, Italy) along an N150°/N330° orientation. With the vibratory source (a shaker truck) working in shear‐wave mode in the frequency range 5–40 Hz, we recorded seismic data using both three‐component velocimeters and 4.5 Hz geophones. These two types of receivers were arranged in linear configuration along two orthogonal orientations: radial and transverse to the direction of the main polarization observed within the fault zone. The two lines of seismic stations allowed us to investigate the polarization evolution as a function of the distance from the source. Results show that when the shear excitation induced by the source is parallel to the direction of observed polarization of the ground motion, the seismic signal propagates efficiently, maintaining the same horizontal polarization induced by the active source. This polarization is well recorded up to distances as large as 300 m from the source. On the contrary, when the shear excitation is orthogonal to the predominant site polarization, the ground excitation loses its initial polarization in less than 50 m away from the source position. At larger distances, the transmitted energy propagates with the natural site polarization independently from the original source polarization. The observations in terms of polarization were combined with surface‐wave analysis, aimed at investigating the dispersion characteristics of the wavefield on the geophone lines. The data suggest that the experimental Rayleigh‐wave dispersion spectra show a more coherent signal over the frequency range along the same orientation of the observed site polarization, supporting a preferential direction in the propagation of surface waves. From inversion of the Rayleigh dispersion curves, we inferred the shear‐wave velocity (Vs) to be in the range of 120–450 m/s in the first 30 m deep of Quaternary volcanic sediments. The dispersion curves are not constant along transverse and radial directions, suggesting the presence of fracture‐induced seismic anisotropy in the near surface. [ABSTRACT FROM AUTHOR]

Published

2019

2. Repeating volcano-tectonic earthquakes at Mt. Etna volcano (Sicily, Italy) during 1999–2009.

Author

Cannata, Andrea, Alparone, Salvatore, and Ursino, Andrea

Abstract

Abstract: Repeating volcano-tectonic (VT) earthquakes, taking place at Mt. Etna during 1999–2009, were detected and analyzed to investigate their behavior. We found 735 families amounting to 2479 VT earthquakes, representing ~38% of all the analyzed VT earthquakes. The number of VT earthquakes making up the families ranges from 2 to 23. Over 70% of the families comprise 2 or 3 VT earthquakes and only 20 families by more than 10 events. The occurrence lifetime is also highly variable ranging from some minutes to ten years. In particular, more than half of the families have a lifetime shorter than 0.5 day and only ~10% longer than 1year. On the basis of these results, most of the detected families were considered “burst-type”, i.e., show swarm-like occurrence, and hence their origin cannot be explained by a temporally constant tectonic loading. Indeed, since the analyzed earthquakes take place in a volcanic area, the rocks are affected not only by tectonic stresses related to the fairly steady regional stress field but also by local stresses, caused by the volcano, such as magma batch intrusions/movements and gravitational loading. We focused on the five groups of families characterized by the longest repeatability over time, namely high number of events and long lifetime, located in the north-eastern, eastern and southern flanks of the volcano. Unlike the first four groups, which similarly to most of the detected families show swarm-like VT occurrences, group “v”, located in the north-eastern sector, exhibits a more “tectonic” behavior with the events making up such a group spread over almost the entire analyzed period. It is clear how both occurrence and slip rates do not remain constant but vary over time, and such changes are time-related to the occurrence of the 2002–2003 eruption. Finally, by FPFIT algorithm a good agreement between directions identified by nodal planes and the earthquake epicentral distribution was generally found. [Copyright &y& Elsevier]

Published

2013

3. Kinematics and strain analyses of the eastern segment of the Pernicana Fault (Mt. Etna, Italy) derived from geodetic techniques (1997-2005)

Author

M. Mattia, F. Guglielmino, S. Consoli, O. Consoli, M. Cantarero, F. Calvagna, A. Bonforte, M. Amore, M. Aloisi, and M. Palano

Subjects

GPS, EDM, ground deformation, Pernicana Fault, Mt. Etna, Meteorology. Climatology, QC851-999, Geophysics. Cosmic physics, QC801-809

Abstract

This paper analyses the ground deformations occurring on the eastern part of the Pernicana Fault from 1997 to 2005. This segment of the fault was monitored with three local networks based on GPS and EDM techniques. More than seventy GPS and EDM surveys were carried out during the considered period, in order to achieve a higher temporal detail of ground deformation affecting the structure. We report the comparisons among GPS and EDM surveys in terms of absolute horizontal displacements of each GPS benchmark and in terms of strain parameters for each GPS and EDM network. Ground deformation measurements detected a continuous left-lateral movement of the Pernicana Fault. We conclude that, on the easternmost part of the Pernicana Fault, where it branches out into two segments, the deformation is transferred entirely SE-wards by a splay fault.

Published

2006

4. Insights into fluid circulation across the Pernicana Fault (Mt. Etna, Italy) and implications for flank instability

Author

Siniscalchi, A., Tripaldi, S., Neri, M., Giammanco, S., Piscitelli, S., Balasco, M., Behncke, B., Magrì, C., Naudet, V., and Rizzo, E.

Subjects

*ROCK permeability, *GEOLOGIC faults, *ELECTRIC resistance, *FLUCTUATIONS (Physics), *STRUCTURAL geology, *VOLCANIC ash, tuff, etc.

Abstract

Abstract: We conducted geophysical–geochemical measurements on a ∼2kmN–S profile cutting across the Pernicana Fault, one of the most active tectonic features on the NE flank of Mt. Etna. The profile passes from the unstable E flank of the volcano (to the south) to the stable N flank and significant fluctuations in electrical resistivity, self-potential, and soil gas emissions (CO2, Rn and Th) are found. The detailed multidisciplinary analysis reveals a complex interplay between the structural setting, uprising hydrothermal fluids, meteoric fluids percolating downwards, ground permeability, and surface topography. In particular, the recovered fluid circulation model highlights that the southern sector is heavily fractured and faulted, allowing the formation of convective hydrothermal cells. Although the existence of a hydrothermal system in a volcanic area does not surprise, these results have great implications in terms of flank dynamics at Mt. Etna. Indeed, the hydrothermal activity, interacting with the Pernicana Fault activity, could enhance the flank instability. Our approach should be further extended along the full extent of the boundary between the stable and unstable sectors of Etna for a better evaluation of the geohazard in this active tectonic area. [Copyright &y& Elsevier]

Published

2010

5. Using a vibratory source at Mt. Etna (Italy) to investigate the wavefield polarization at Pernicana Fault

Author

Fabrizio Cara, Michele Punzo, Antonio Rovelli, Giuseppe Di Giulio, Pier Paolo Bruno, Di Giulio, G., Punzo, M., Bruno, Pier Paolo Gennaro, Cara, F., and Rovelli, A.

Subjects

Seismic vibrator, Site effect, Data acquisition, Seismic polarization, Polarization (waves), Surface wave, Physics::Geophysics, Pernicana Fault, Geophysics, Vibroseis, Seismology, Geology

Abstract

The paper presents the results of a controlled-source seismic experiment performed using a vibratory source capable of producing harmonic vibrations. The survey aimed at investigating the horizontal directional amplification mechanism observed at the Pernicana Fault (Mt. Etna in Sicily, Italy) along an N150°/N330° orientation. With the vibratory source (a shaker truck) working in shear-wave mode in the frequency range 5–40 Hz, we recorded seismic data using both three-component velocimeters and 4.5 Hz geophones. These two types of receivers were arranged in linear configuration along two orthogonal orientations: radial and transverse to the direction of the main polarization observed within the fault zone. The two lines of seismic stations allowed us to investigate the polarization evolution as a function of the distance from the source. Results show that when the shear excitation induced by the source is parallel to the direction of observed polarization of the ground motion, the seismic signal propagates efficiently, maintaining the same horizontal polarization induced by the active source. This polarization is well recorded up to distances as large as 300 m from the source. On the contrary, when the shear excitation is orthogonal to the predominant site polarization, the ground excitation loses its initial polarization in less than 50 m away from the source position. At larger distances, the transmitted energy propagates with the natural site polarization independently from the original source polarization. The observations in terms of polarization were combined with surface-wave analysis, aimed at investigating the dispersion characteristics of the wavefield on the geophone lines. The data suggest that the experimental Rayleigh-wave dispersion spectra show a more coherent signal over the frequency range along the same orientation of the observed site polarization, supporting a preferential direction in the propagation of surface waves. From inversion of the Rayleigh dispersion curves, we inferred the shear-wave velocity (Vs) to be in the range of 120–450 m/s in the first 30 m deep of Quaternary volcanic sediments. The dispersion curves are not constant along transverse and radial directions, suggesting the presence of fracture-induced seismic anisotropy in the near surface.

Published

2019

6. Insights into fluid circulation across the Pernicana Fault (Mt. Etna, Italy) and implications for flank instability

Author

Sabatino Piscitelli, Simona Tripaldi, Enzo Rizzo, V. Naudet, Agata Siniscalchi, Salvatore Giammanco, C. Magrì, Marco Neri, Marianna Balasco, and Boris Behncke

Subjects

Etna magnetic electrical methods, geography, Flank, geography.geographical_feature_category, structural geology, Fault (geology), Instability, Hydrothermal circulation, NO, Pernicana Fault, fluid circulation, Tectonics, Geophysics, Volcano, Geochemistry and Petrology, Geohazard, Petrology, Structural geology, Geology, Seismology

Abstract

article i nfo We conducted geophysical-geochemical measurements on a ∼ 2k m N-S profile cutting across the Pernicana Fault, one of the most active tectonic features on the NE flank of Mt. Etna. The profile passes from the unstable E flank of the volcano (to the south) to the stable N flank and significant fluctuations in electrical resistivity, self-potential, and soil gas emissions (CO2, Rn and Th) are found. The detailed multidisciplinary analysis reveals a complex interplay between the structural setting, uprising hydrothermal fluids, meteoric fluids percolating downwards, ground permeability, and surface topography. In particular, the recovered fluid circulation model highlights that the southern sector is heavily fractured and faulted, allowing the formation of convective hydrothermal cells. Although the existence of a hydrothermal system in a volcanic area does not surprise, these results have great implications in terms of flank dynamics at Mt. Etna. Indeed, the hydrothermal activity, interacting with the Pernicana Fault activity, could enhance the flank instability. Our approach should be further extended along the full extent of the boundary between the stable and unstable sectors of Etna for a better evaluation of the geohazard in this active tectonic area.

Published

2010

7. Ground deformation modeling of flank dynamics prior to the 2002 eruption of Mt. Etna

Author

Bonforte, Alessandro, Gambino, Salvatore, Guglielmino, Francesco, Obrizzo, Francesco, Palano, Mimmo, and Puglisi, Giuseppe

Published

2007

8. Repeating volcano-tectonic earthquakes at Mt. Etna volcano (Sicily, Italy) during 1999-2009

Author

Andrea Cannata, A. Ursino, and Salvatore Alparone

Subjects

geography, geography.geographical_feature_category, Mt. Etna volcano, Pernicana fault, Repeating earthquakes, Volcano tectonic earthquakes, Geology, Slip (materials science), Stress field, Tectonics, Etna volcano, Volcano, Seismology

Abstract

Repeating volcano-tectonic (VT) earthquakes, taking place at Mt. Etna during 1999–2009, were detected and analyzed to investigate their behavior. We found 735 families amounting to 2479 VT earthquakes, representing ~ 38% of all the analyzed VT earthquakes. The number of VT earthquakes making up the families ranges from 2 to 23. Over 70% of the families comprise 2 or 3 VT earthquakes and only 20 families by more than 10 events. The occurrence lifetime is also highly variable ranging from some minutes to ten years. In particular, more than half of the families have a lifetime shorter than 0.5 day and only ~ 10% longer than 1 year. On the basis of these results, most of the detected families were considered “burst-type”, i.e., show swarm-like occurrence, and hence their origin cannot be explained by a temporally constant tectonic loading. Indeed, since the analyzed earthquakes take place in a volcanic area, the rocks are affected not only by tectonic stresses related to the fairly steady regional stress field but also by local stresses, caused by the volcano, such as magma batch intrusions/movements and gravitational loading. We focused on the five groups of families characterized by the longest repeatability over time, namely high number of events and long lifetime, located in the north-eastern, eastern and southern flanks of the volcano. Unlike the first four groups, which similarly to most of the detected families show swarm-like VT occurrences, group “v”, located in the north-eastern sector, exhibits a more “tectonic” behavior with the events making up such a group spread over almost the entire analyzed period. It is clear how both occurrence and slip rates do not remain constant but vary over time, and such changes are time-related to the occurrence of the 2002–2003 eruption. Finally, by FPFIT algorithm a good agreement between directions identified by nodal planes and the earthquake epicentral distribution was generally found.

Published

2013

9. Environmental hazard of capable faults: the case of the Pernicana fault (Mt. Etna, Sicily)

Author

Serva, Leonello, Vittori, Eutizio, Azzaro, Raffaele, Michetti, Alessandro Maria, and Ferreli, Luca

Subjects

URBAN planning, EARTH sciences, SEISMOLOGY

Abstract

When dealing with hazard, the concept of fault capability (the probability of significant surface displacement in the near future) is more useful than the generic and often misleading concept of fault activity. The example of the Pernicana fault, located in the north-easternflank of the Mt. Etna volcano is used here to illustrate the damage which can be expected in an urbanised area from a capable fault, in this case characterized by 'aseismic' creep along part of its length. Along this fault, buildings, roads and other essential lifelines are being affected by slow, left-lateral displacement. The Pernicana fault is only one of a set of structures in the area whose movement, either connected to seismicity or not, is producing severe damage. First identified at the end of the last century, this source of hazard is, nevertheless, still poorly considered by planners and technicians. InItaly fault creep is quite rare outside the Etna region, but fault capability associated with strong earthquakes is relatively frequent, based on historical and palaeoseismological data, and is a feature that should be taken into account for hazard reduction programs. [ABSTRACT FROM AUTHOR]

Published

1998

10. Kinematics and strain analyses of the eastern segment of the Pernicana Fault (Mt. Etna, Italy) derived from geodetic techniques (1997-2005)

Author

Marco Aloisi, B. Puglisi, Alessandro Bonforte, Massimo Cantarero, Orazio Consoli, Salvatore Consoli, Francesco Guglielmino, Mario Mattia, Mimmo Palano, M. Amore, Giuseppe Puglisi, and Francesco Calvagna

Subjects

geography, EDM, geography.geographical_feature_category, business.industry, GPS, Mt. Etna, lcsh:QC801-809, Geodetic datum, Kinematics, Fault (geology), Deformation (meteorology), lcsh:QC851-999, Geodesy, Pernicana Fault, lcsh:Geophysics. Cosmic physics, Geophysics, ground deformation, Global Positioning System, lcsh:Meteorology. Climatology, business, Seismology, Geology

Abstract

This paper analyses the ground deformations occurring on the eastern part of the Pernicana Fault from 1997 to 2005. This segment of the fault was monitored with three local networks based on GPS and EDM techniques. More than seventy GPS and EDM surveys were carried out during the considered period, in order to achieve a higher temporal detail of ground deformation affecting the structure. We report the comparisons among GPS and EDM surveys in terms of absolute horizontal displacements of each GPS benchmark and in terms of strain parameters for each GPS and EDM network. Ground deformation measurements detected a continuous left-lateral movement of the Pernicana Fault. We conclude that, on the easternmost part of the Pernicana Fault, where it branches out into two segments, the deformation is transferred entirely SE-wards by a splay fault.