ALBERT

Description: A seguito del terremoto del 6 aprile sono state eseguite campagne di misure geochimiche con lo scopo di verificare le modificazioni indotte dal terremoto, le relazioni fluidi/strutture tettoniche e l’origine dei fluidi (Italiano et al., 2001, 2004, 2005, 2007a, b, 2008, 2009a, b). Sono stati prelevati campioni di gas da pozzi ubicati in area epicentrale noti nella zona come “soffianti”, sono state eseguite misure di degassamento al suolo nelle aree interessate da fratturazione (indicazioni da Emergeo) e sono stati scaricati i dati di flusso di CO2 da una stazione remota ubicata in Umbria (San Faustino). Le misure di degassamanto al suolo sono state eseguite con i metodi generalmente applicati e noti in letteratura (camera di accumulo e concentrazione dinamica), ma il metodo della camera di accumulo è stato subito abbandonato perchè sensibile allo stato di imbibizione dello strato superficiale del terreno. Le misure sono state eseguite con il metodo della concentrazione dinamica (tubo inserito nel terreno a 50 cm di profondità sotto un flusso costante di 1l/min. di gas) hanno fornito utili indicazioni di un degassamento attivo con concentrazioni nel suolo di CO2 fino al 8% e contenuti di radon fino. Dai siti a maggiore concentrazione di CO2 sono stati prelevati campioni di gas del suolo per misure di laboratorio (composizione chimica ed isotopica). Le analisi eseguite sui gas campionati mostrano che, accanto alla componente atmosferica, è presente un tenore anomalo di CO2 (fino a 30-40 volte superiore alla concentrazione in aria) con composizione isotopica diversa dall’atmosfera (impoverimento in isotopo pesante) associata ad elio con contributo di tipo crostale (3He/4He inferiore a quello dell’aria) testimoniando l’esistenza di una fase di degassamento attivo di gas di origine crostale. L’esistenza di un degassamento attivo induce quesiti su quale sia l’origine dei fluidi emessi (in particolare la CO2) e quali siano le loro relazioni con il terremoto. La CO2 emessa in area ipocentrale potrebbe essere l’esito del degassamento da reservoir preesistenti. Alternativamente, dati sperimentali hanno accertato che è possibile produrre CO2 da stress meccanico su rocce carbonatiche (Italiano et al., 2007b, 2008) ed in particolare per l’Appennino centro settentrionale è stato proposto che parte della CO2 emessa sia originata da un processo simile a quello sperimentato in laboratorio che può avvenire durante le fasi di deformazione e durante la rottura. Tenuto conto anche delle anomalie di radon registrate in occasione del sisma, è necessario accertare quale sia l’origine, la circolazione e le modalità di rilascio dei fluidi, fornendo un modello che giustifichi tutte le anomalie osservate e sia utile per interpretazioni future.

Description: OGS - Trieste Provincia Trieste EUCENTRE Codevintec

Description: Published

Description: 28° Convegno Nazionale Gruppo Nazionale di Geofisica della Terra Solida - Trieste 16-19 Novembre 2009

Description: 3.2. Tettonica attiva

Description: open

Description: The Miano borehole of 1047 m depth is located close to the river Parma in the Northern Apennines, Italy. A measuring station is installed to observe the discharge of fluids continuously since November 2004. The upwelling fluid of this artesian well is a mixture of thermal water and methane as main components. In non-seismogenic areas, we would expect a relative constant fluid emission perhaps overlaid with long term variations from that kind of deep reservoirs during the time. However, the continuously record of the fluid emission, in particular the water discharge, the gas flow rate and the water temperature, show periods of stable values interrupted by anomalous periods of fluctuations in the recorded parameters. The anomalous variations of these parameters are of low amplitude in comparison to the total values but significant in their long-term trend. Meteorological influences of rain and barometric pressure were not detected in recorded data probably due to reservoir depth and relatively high reservoir overpressure. Influences due to the ambient temperature after the discharge were evaluated by statistical analysis. We consider that recorded changes in fluid emission parameters can be interpreted as a mixing process of different fluid components in depth by variations in pore pressure as result of seismogenic stress variation. Local seismicity was analyzed in comparison to fluid’s physico-chemical data. The analysis supports the idea of an influence to fluid transport conditions due to geodynamic processes exist. Water temperature data show frequent anomalies probably connected with possible precursory phenomena of local seismic events.

Description: In press

Description: 3.2. Tettonica attiva

Description: JCR Journal

Description: open

Description: The possibility of forecasting seismic events has always attracted people living over earthquake-prone areas, and many empirical methods were proposed in order to predict earthquakes. Even thought some of them successfully predicted an event, none of them never became a reliable forecasting method (Geophys. Jour. Int, 1997). Recent panels and meetings allowed to sum up the situation of the Earthquake prediction and almost all the scientists have agreed that the attempts made all over the world did not provide useful results, thus, statistical approaches to the seismic hazard assessment, continue to offer the most cost-effective means to reduce earthquake-related losses. With the aim to gain a better insight of the processes occurring at various crustal levels during the seismogenesis many research activities based on the information carried by the fluids have been recently developed, although the scientific community have the feeling to be far from any possibility of predicting an earthquake, if “prediction” means the precise indication of time and site hit by the seismic shock. The seismic crisis that recently hit the Central Apennines (Italy, Abruzzo Region) has clearly shown that the role of geochemistry during any seismic emergency is a debated question: the seismological information is provided and used besides potentially useful geochemical information that do not still have a practical role. The long-term geochemical monitoring carried out during the last 15 years over the Italian seismic areas of Northern Italy (Friuli/Slovenia border, Tosco-Emiliano Apennines), Central Italy (Central-Northern Apennines of Umbria-Marche-Abruzzo-Latium Regions), and Southern Apennines (Basilicata-Irpinia area, Calabria Region, Messina strait and Peloritani-Nebrodi Mountains; see references) has allowed to model the origin and circulation of the fluids and to interpret their temporal variations. Fluids, in fact, are natural and fast carriers of information from the deep crustal layers, as such the collected results represent a powerful tool to reveal the presence of hidden structures as well as to evaluate the fault’s activity over seismic-prone areas. In fact, as observed at global scale, any tectonic line under stress deforms before undergoing rupture, and causes modifications to the fluids’ circulation and their geochemical features during the whole seismogenesis. Those modifications may speed up in proximity of rupture events and many geochemical parameters behave as forerunners. The ruptures responsible for the seismic sequences of Umbria-Marche (1997-98) and Abruzzo (2009) taught us how to use the information coming from the fluids. Unfortunately, attempts to move back to old-fashioned earthquake predictions caused alarms due to incorrect use of the scientific information (moreover taking into account only one parameter: radon), and have the consequence of credibility loss of the whole scientific community. With this information in our hands we have to ask to ourselves what the role of geochemistry has to become within the very delicate mainframe of seismic hazard limitation. A long-term monitoring activity aimed to take a census and to define the origin and composition of the circulating fluids for every seismic-prone area, besides the continuous monitoring of selected parameters, makes the necessary geochemical tools to identify the existence of tectonic structures and to evaluate their seismogenic activity

Description: INGV, SNGN Romangaz, Thermo Scientific, Environmental Health Center

Description: Published

Description: Cluj-Napoca, Romania

Description: 3.2. Tettonica attiva

Description: restricted

Description: A periodic sampling of the groundwaters and dissolved and free gases in selected deep wells located in the area affected by the May-June 2012 southern Po Valley seismic sequence has provided insight into seismogenic-induced changes of the local aquifer systems. The results obtained show progressive changes in the fluid geochemistry, allowing it to be established that deep-seated fluids were mobilized during the seismic sequence and reached surface layers along faults and fractures, which generated significant geochemical anomalies. The May-June 2012 seismic swarm (mainshock on May 29, 2012, M 5.8; 7 shocks M 〉5, about 200 events 3 〉 M 〉 5) induced several modifications in the circulating fluids. This study reports the preliminary results obtained for the geochemical features of the waters and gases collected over the epicentral area from boreholes drilled at different depths, thus intercepting water and gases with different origins and circulation. The aim of the investigations was to improve our knowledge of the fluids circulating over the seismic area (e.g. origin, provenance, interactions, mixing of different components, temporal changes). This was achieved by collecting samples from both shallow and deep-drilled boreholes, and then, after the selection of the relevant sites, we looked for temporal changes with mid-to-long-term monitoring activity following a constant sampling rate. This allowed us to gain better insight into the relationships between the fluid circulation and the faulting activity. The sampling sites are listed in Table 1, along with the analytical results of the gas phase.

Description: Published

Description: 815-821

Description: 3.2. Tettonica attiva

Description: JCR Journal

Description: open

Description: Results from a geochemical investigation of fluids (thermal waters and venting gases) discharged along the East Anatolian Fault (EAFZ, Turkey) has been carried out. The EAFZ runs in a northeasterly direction, starting from the northern end of the Dead Sea Transform (Maras Triple Junction) and ending at the Karliova Triple Junction where it crosses the North Anatolian Fault. The EAFZ is a major strike-slip fault zone forming the transform type tectonic boundary between the Anatolian and the Arabian Plates. The East and North Anatolian faults together accommodate the westward motion of the Anatolian Plate as it is squeezed out by the ongoing collision with the Eurasian Plate. The investigations have been carried out over a 250 km-long segment from Malatya to the Karliova Triple Junction area. Samples of both free and dissolved gases were taken from cold and thermal springs displaying outlet temperatures in the range of 17-67°C. The sampling procedures allowed the determination of the chemical and isotopic features of bubbling as well as dissolved gases. The gas phase is always made of CO2-dominated fluids with variable amounts of nitrogen and CH4. The isotopic ratios of helium cover a range spanning from crustal to magmatic-type values in both free and dissolved gases. The isotopic composition of carbon ( CO2 ) shows values in the range of – 5.6 /-0.2 ‰ vs PDB for the bubbling gases in contrast with the positive values (from 0.3 to 3.4‰ vs PDB) detected in the dissolved carbon. Consistently with previous studies on the North Anatolian Fault Zone, the preliminary results show variable contribution of mantle-derived fluids (e.g. from 3 to about 70% of mantle helium) along the fault and the occurrence of intense gas-water interaction (GWI) processes. The intense carbon fractionation during gas bubbling with preferential dissolution of the heavy C isotope (13C) and the highest 3-helium abundance in coincidence with the lowest outlet temperatures, provide useful indications to constrain the GWI processes.

Description: Unpublished

Description: La Jolla, California, USA

Description: 3.2. Tettonica attiva

Description: restricted

Description: The first comprehensive geochemical data-set of the fluids circulating over a 14,000 km2-wide seismicprone area of the Southern Apennines, Calabria Region (Italy), is presented here. The geochemical investigations were carried out with the twofold aim of constraining the origin and interactions of the circulating fluids and to investigate possible relationships with local faults. Sixty samples of both thermal and cold waters were collected, from which the dissolved gases were extracted. The geochemical features of the water samples display different types and degrees of water–rock interactions, irrespective of the outlet temperature. The calculated equilibrium temperatures of the thermal waters (60–160 C) and the low heat flow of thewhole study area, are consistent with a heating process due to deep water circulation and rapid upflow through lithospheric structures. The composition of the dissolved gases reveals that crustal-originating gases (N2 and CO2-dominated) feed all the groundwaters. The 3He/4He ratios of the dissolved He, in the range of 0.03–0.22Rac for the thermal waters and 0.05–0.63Rac for the cold waters (Rac = He isotope ratio corrected for atmospheric contamination), are mainly the result of a two-component (radiogenic and atmospheric) mixing, although indications of mantle-derived He are found in some cold waters. As the study area had been hit by 18 of the most destructive earthquakes (magnitude ranging from 5.9 to 7.2) occurring over a 280-a time span (1626–1908) in the Southern Apennines, the reported results on the circulating fluids may represent the reference for a better inside knowledge of the fault-fluid relationships and for the development of long-term geochemical monitoring strategies for the area.

Description: Published

Description: 540–554

Description: 3.2. Tettonica attiva

Description: JCR Journal

Description: open

Description: The Miano borehole, 1047 m deep, is located close to the river Parma in the Northern Apennines, Italy. A measuring station has been installed to observe the discharge of fluids continuously since November 2004. The upwelling fluid of this artesian well is a mixture of thermal water and CH4 as main components. In non-seismogenic areas, a relatively constant fluid emission would be expected, perhaps overlaid with long term variations from that kind of deep reservoir over time. However, the continuous record of the fluid emission, in particular the water discharge, the gas flow rate and the water temperature, show periods of stable values interrupted by anomalous periods of fluctuations in the recorded parameters. The anomalous variations of these parameters are of low amplitude in comparison to the total values but significant in their long-term trend. Meteorological effects due to rain and barometric pressure were not detected in recorded data probably due to reservoir depth and relatively high reservoir overpressure. Influences due to the ambient temperature after the discharge were evaluated by statistical analysis. Our results suggest that recorded changes in fluid emission parameters can be interpreted as a mixing process of different fluid components at depth by variations in pore pressure as a result of seismogenic stress variation. Local seismicity was analyzed in comparison to the fluid physico-chemical data. The analysis supports the idea that an influence on fluid transport conditions due to geodynamic processes exists. Water temperature data show frequent anomalies probably connected with possible precursory phenomena of local seismic events.

Description: Published

Description: 555–571

Description: 3.2. Tettonica attiva

Description: JCR Journal

Description: open

Description: On April 6th, 2009, a seismic crisis hit the Central Italy killing more than 300 people among the ruins and the polemics caused by an unheeded alarm based on radon data. That episode cannot be forgotten not because the number of victims, lower than in other events, but because at global scale the main question was what it was the role of the scientific research to effectively reduce the seismic hazard. The Earthquake prediction still represents one, among the biggest, unsolved problems for the whole humankind. The possibility of forecasting seismic events has always attracted people living over earthquakeprone areas, and many empirical methods have been proposed in order to predict earthquakes. Summing up the situation of the Earthquake prediction we have to agree that the attempts made all over the world did not provide useful results, thus, statistical approaches to the seismic hazard assessment, continue nowadays to offer the most cost-effective means to reduce earthquake-related losses. However the limit of such an approach is that it cannot provide information on natural processes occurring during the seismogenesis. To gain a better insight of those processes occurring at various crustal levels during the seismogenesis, namely to develop a deterministic approach, many research activities based on the information carried by the fluids have been recently developed, although the scientific community have the feeling to be far from any possibility of predicting an earthquake, if “prediction” means the precise indication of time and site hit by the seismic shock. The results of long-term geochemical monitoring carried out during the last 15 years over the Italian seismic areas of Northern Italy (Friuli/Slovenia border), Central Italy (Central-Northern Apennines of Umbria-Marche-Abruzzo-Latium Regions), and Southern Apennines (Basilicata-Irpinia area, Calabria Region, Messina strait and Peloritani-Nebrodi Mountains) has allowed to model and to interpret the origin, circulation and temporal variations of fluids over seismogenic faults. To share such kind of results with other scientific information (geophysical, geological, archaeological etc) thus to have a cooperative multidisciplinary approach to the wide problem of forecast prediction may provide the most powerful tool to better understand the natural processes. Finally, to couple the statistical methods with the deterministic results will take a step forward to significantly reduce the seismic hazard for any seismic-prone area.

Description: Unpublished

Description: Elazig, Turkey

Description: 3.2. Tettonica attiva

Description: restricted

Description: Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Massachusetts Institute of Technology and Woods Hole Oceanographic Institution October 1993

Description: This thesis investigates a new method for predicting the farfield scattered pressure of a plane wave due to an infinite cylinder of noncircular cross section. Both impenetrable and penetrable :fluid boundary condi tions will be treated for several types of cross sections and for a large frequency range. This new method requires the conformal mapping of both the exterior and interior of a closed surface to a semi-infinite strip. Numerically efficient algorithms wi ll be presented for both of these cases. A new method for satisfying the boundary conditions will be developed, as well as an efficient algorithm for generating the required modal functions on the boundary. Numerical results are presented for cross sections in the shape of an ellipse, square, and three leaf clover. In all cases, the results compare extremely well with exact or high frequency asymptotic results.