ALBERT

Description: Mt. Vesuvius (southern Italy) is one of the volcanoes that poses the greatest risk in the world because of its highly explosive eruptive style and its proximity to densely populated areas. The urbanization around Mt. Vesuvius began in ancient times, and the impact of eruptions on human activities has been severe. This is testified to by the ruins of Pompeii, which are covered by the products of the plinian eruption that took place in A.D. 79 (Sigurdsson et al. 1985), and more recently by the published reports of the eruptions that occurred from 1631 to 1944. For these reasons, Mt. Vesuvius was also one of the first volcanoes to be equipped with monitoring instruments. Pioneering instrumental observations began just before the second half of the 1800s, when the Vesuvius Observatory was founded in 1841 (Imbò 1949). At that time, Vesuvius was very active (Ricciardi 2009), and its effusive and explosive eruptions often caused damage to the surrounding areas. At the same time, it was a famous tourist attraction that drew travelers from all over the world (Gasparini and Musella 1991). Since the middle of the 1800s, at least 12 eruptions have occurred that have been superimposed on persistent intra-crater activity that has been characterized by Strombolian explosions and by the formation of small lava lakes. The last eruption occurred on 18 March 1944 and marked a change in the status of Mt. Vesuvius, as it entered a closed-conduit phase that persists today. Following this last eruption, a change occurred in the 1960s, as documented by an increase in the occurrence rate of earthquakes. Since 1972, the monitoring of Mt. Vesuvius has improved over time and become more systematic, so that there is a remarkable dataset relating to the current phase of quiescence. Over more than a century and a half of observations, many monitoring instruments have been used for Mt. Vesuvius, including early seismometers, several of which are now kept in the Museum of Volcanology of the Vesuvius Observatory. The present monitoring system is based on seismological, geodetical geodetical, and geochemical observations performed using an instrumental network that was designed on the basis of the current state of the volcano while also taking into account the likely scenario of future unrest.

Description: Published

Description: 625-634

Description: 1.4. TTC - Sorveglianza sismologica delle aree vulcaniche attive

Description: JCR Journal

Description: reserved

Description: Stress can undergo rapid temporal changes in volcanic environments, and this is particularly true during eruptions. We use two independent methods, coda wave interferometry (CWI) and shear wave splitting (SWS) analysis to track stress related wave propagation effects during the waning phase of the 2002 NE fissure eruption at Mt Etna. CWI is used to estimate temporal changes in seismic wave velocity, while SWS is employed to monitor changes in elastic anisotropy. We analyse seismic doublets, detecting temporal changes both in wave velocities and anisotropy, consistent with observed eruptive activity. In particular, syn-eruptive wave propagation changes indicate a depressurization of the system, heralding the termination of the eruption, which occurs three days later.

Description: Published

Description: 1779-1788

Description: 1.4. TTC - Sorveglianza sismologica delle aree vulcaniche attive

Description: JCR Journal

Description: reserved

Description: A series of computer microtomography experiments are reported which were performed by using a third-generation synchrotron radiation source on volcanic rocks from various active hazardous volcanoes in Italy and other volcanic areas in the world. The applied technique allowed the internal structure of the investigated material to be accurately imaged at the micrometer scale and three-dimensional views of the investigated samples to be produced as well as three-dimensional quantitative measurements of textural features. Thegeometryof thevesicle (gas-filledvoid) network in volcanic products of both basaltic and trachytic compositions were particularly focused on, as vesicle textures are directly linked to the dynamics of volcano degassing. This investigation provided novel insights into modes of gas exsolution, transport and loss in magmas that were not recognized in previous studies using solely conventional two- dimensional imaging techniques. The results of this study are important to understanding the behaviour of volcanoes and can be combined with other geosciences disciplines to forecast their future activity.

Description: In press

Description: 2.3. TTC - Laboratori di chimica e fisica delle rocce

Description: JCR Journal

Description: reserved

Description: We propose a method for analyzing the polarization of three-component digital recordings using the discrete wavelet transform (DWT). This method allows for the automatic detection and separation of seismic phases that have a coherent linear or elliptical polarization. It can be correctly used in the analysis of seismic signals relating to volcanic activity because they arise from a complex wave field that consists of near-field and far-field components that have frequency-dependent polarization. First, the analytic extension of the signal is decomposed using DWT, then each single component is used to determine a local complex polarization vector in the timescale domain. This analysis reveals the presence of seismic phases with coherent polarization over a range of DWT scales and finite temporal intervals. Using the orthogonality property of the DWT, it is possible to isolate a single coherent component, reconstructing it in the time domain and computing the full polarization tensor. This procedure can be fully automated, introducing a quantitative definition of wavelet polarization coherence on the DWT dyadic grid. A recursive algorithm (called POLWAV) starts from the wavelet coefficient with the highest modulus, and then selects all of the neighbors that show coherence with it above a given threshold. We show how the POLWAValgorithm can be used for separating wave-field components and for detecting coherent seismic phases on continuous recordings. Example applications to actual seismic recordings at Stromboli Volcano (Tyrrhenian Sea) are presented.

Description: Published

Description: 670–683

Description: 1.4. TTC - Sorveglianza sismologica delle aree vulcaniche attive

Description: JCR Journal

Description: reserved

Description: Modern seismic networks have grown to become increasingly complex infrastructures, composed of hundreds of devices and data streams scattered over wide geographic regions. Among the components of such networks are heterogeneous seismic and environmental sensors, digitizers, data loggers, data collection servers, wired and wireless communication hardware, and other devices and software subsystems charged with different data handling tasks, such as continuous data storage or analysis. In order to be effectively managed, a seismic network therefore needs a tiered software application. This application encompasses tasks that range from the low-level (hardware monitoring for failure detection) to the mid-level (data quality control) to the high-level (managing the final output of the network: recorded events, waveforms, and parametric data). At the same time such an application should provide a centralized and easy-to-use graphical user interface (GUI). Over the past two decades, several institutions and commercial companies have devoted great efforts to the development of software tools to manage and centralize the data acquisition and analysis for regional to global seismic networks. Among the most valuable products worth mentioning are: Earthworm, an open-source real-time seismic management system developed by the U.S. Geological Survey (Johnson et al. 1995); Antelope, a commercial real-time system for environmental data collection, developed by Boulder Real Time Technologies (BRTT 2008); and the more recent SeisComP (Hanka et al. 2000), an open-source tool for real-time data acquisition and analysis developed by the German Research Centre for Geosciences (GFZ-Potsdam). Although well-suited for real-time data collection and analysis, these systems do not currently provide advanced features for managing the infrastructure of a seismic network, such as state-of-health monitoring of the instrumentation or tracking all the network appliances.Trying to fill this gap, Instrumental Software Technologies (ISTI 2008) has recently developed SeisNetWatch (SeisNetWatch 2008), a tool for monitoring and controlling the data quality and the status of several types of data loggers and real-time seismic management systems. This desktop- and Web-accessible tool features a core system and a user interface written in Java, plus several “agents” each interacting with a particular piece of hardware or system. During the development of the Irpinia Seismic Network (ISNet) in southern Italy (Weber et al. 2007), we decided to address our needs of hardware monitoring and data management by developing our own solution, a Web-based application called SeismNet Manager. The application is designed as a graphical front-end to ISNet for internal and external users of the network, as well as its administrators, with an interface that is simple to use. SeismNet Manager leverages an instrument database and a seismic database to keep track of the hardware components that comprise the network (such as stations, servers, devices) and the data they produce (such as recorded waveforms and events). The application, universally accessible through a Web browser, fulfills the following needs: • to keep a detailed inventory of the multiple components that constitute a seismic network, including stations, sensors, data loggers, network hardware, generic hardware, data servers, and communication links; • to maintain a historical record of the installations and of the configuration details, as well as of the mutual connections of said components; • to perform real-time monitoring of some of the devices (hardware state and “health” problems, quality of the output) for alerting network operators of problems and complementing the seismic data; • to manage the seismic data produced by the network, obtained either through automatic data retrieval procedures or manual insertion by administrators (detected events, seismic recordings, parametric information) and to perform some routine tasks on returned data, including inspection, filtering, picking, and flagging. • to offer a Web-based interface that lets data consumers or network operators insert, edit, search, download and visualize all the available information (as tables, graphs, maps, waveform plots, and 3D renderings). To accomplish these goals, which are not specific to ISNet but are shared by most seismic networks, we made use of opensource technological solutions such as Linux (Debian 2008), PostgreSQL (PostgreSQL 2008), and Tomcat (Tomcat 2008). Flexibility and configurability was a priority, so that we could tailor SeismNet Manager to the specific needs and actual hardware of different networks and could manage multiple networks. At the same time, SeismNet Manager is not designed as a “be-all do-all” system performing every task needed in a seismic network, some of which are better left to specialized and standard software packages. For instance, in ISNet the continuous data acquisition and storage from the stations and the real-time seismic data processing for seismic early warning are implemented elsewhere, as discussed below. SeismNet Manager is thus built on top of the various elements and subsystems already operating in a network.

Description: Published

Description: 420-430

Description: 5.2. TTC - Banche dati di sismologia strumentale

Description: JCR Journal

Description: reserved