ALBERT

Description: Phospholipase Cε (PLCε) has been characterized as a direct effector of Ras in vitro and in cellular systems; however, the role of PLCε in tumorigenesis and its link to Ras in this context remain unclear. To assess the role of PLCε in Ras-driven cancers, we generated two new mouse strains:...

Description: The opening of a new magnetic observatory is one of the activities aimed at by the creation of a scientific base at DomeC, Antarctica (lat. 75° 06’S, long. 123° 21’E, elev. 3200m). There are many reasons supporting this objective: all Antarctic magnetic observatories providing absolute values are located along the shore and are therefore subject to coast effects and crustal field contamination. DomeC and Vostok will be so far the sole observatories free from these effects. On one hand, high latitude absolute observatories are very useful to global or regional modeling based upon satellite data, because, at high latitudes, only total field measurements can be used due to the strong influence of field aligned currents. On the other hand, the availability of magnetic data from the well distributed observatories of Terra Nova Bay (TNB), Scott Base (SBA), Dumont d’Urville (DRV), Casey (CSY) and Vostok (VOS) will provide strong support to auroral and polar cap ionosphere studies as well as asymmetry analyses between Northern and Southern hemispheres. This paper summarizes the results gathered during three summer campaigns, in 1999-2000, 2001 and 2003-2004.

Description: Published

Description: Kakioka Magnetic Observatory / Tsukuba Center for Institutes, Japan

Description: 1.6. Osservazioni di geomagnetismo

Description: 3.4. Geomagnetismo

Description: open

Description: These reports deal with activities undertaken at the Geomagnetic Observatory TNB in Antarctica during the austral summers 2001-2002 and 2002-2003. Since the Observatory was located very close to the Base, where the growing human activity gave rise to an increased artificial electromagnetic noise, during this campaign, the Observatory has been moved to a new site, called OASI, about 1 km away from the old site. In austral summer 2001-2002, geomagnetic absolute measurements have been performed at both sites, in order to evaluate possible spatial gradients between them. Conversely, the variometer measurements have been carried out only at the new site.

Description: Istituto Nazionale di geofisica e Vulcanologia

Description: Published

Description: 1.6. Osservazioni di geomagnetismo

Description: open

Description: This report deals with activities undertaken at the Antarctic Italian Geomagnetic Observatory during the austral summer 2003-2004. The coordinates of the Observatory at OASI are the following: Geographic latitude: 74.6936°S Geographic longitude: 164.0975°E Corrected Geomagnetic latitude (IGRF00): 80.00°S Corrected Geomagnetic longitude (IGRF00): 306.94°E Magnetic local time midnight: 08:11 UT This report describes the activities performed from November 9, 2003 to December 3, 2004. For the present work H, D, and Z INTERMAGNET formatted data from the fluxgate magnetometer have been used.

Description: Istituto Nazionale di Geofisica e Vulcanologia

Description: Published

Description: 1.6. Osservazioni di geomagnetismo

Description: open

Description: The 2009 L’Aquila seismic sequence, whose main shock (Ml 5.8, Mw 6.3) occurred on April 6th at 1:32 UTC, is still ongoing (August 2009) along the central Apenninic Belt (Abruzzo region, central Italy). The main earthquake was destructive and caused 300 casualties; its epicenter has been located at 42.35°N, 13.38°E, at a depth of around 10 km. The main shock was preceded by a long seismic sequence, started several months before (i.e., December 2008, with a total of 300 earthquakes with Mlmax = 4.0). After the April 6th main event, two other earthquakes struck the area on April 7th and 9th, with Ml 5.3 and 5.1, respectively. A lot of evidences stress the role of the pore-pressure evolution of deep fluids in generating the L’Aquila sequence (e.g. Vp/Vs anomalous ratio, Chiarabba C., 2009 personal communication) as occurred for the Umbria Marche (central Italy) 1997-1998 seismic sequence (Quattrocchi, 1999 and references herein). The entire sequence highlights more than one seismogenic segment activated along a main NW-SE-trending Apenninic lineament (Fig. 1). Soon after the strongest event, our group (UF “Fluid Geochemistry, Geological Storage and Geothermics”, Department Rome 1, INGV) carried out a geochemical study throughout the seismically activated area by sampling around 600 soil gas points and around 70 groundwater points (springs and wells). The main goal of this study was the comprehension of both the behaviour and the geometry of the activated fault segments by means the application of specific geochemical methods, already exploited in other Italian seismic and volcanic areas (Quattrocchi et al., 2000; Pizzino et al., 2004; Quattrocchi et al., 2008; Voltattorni et al., 2009).In particular, here we discuss only the results gathered by measuring soil gases, considering fluxes of CO2 and CH4 as well as concentrations of radon, CO2, CH4, He, H2, N2, H2S, O2, and other minor geogas (i.e. light hydrocarbons) in the main sectors of the activated seismic sequence (see the red box in figure 1). The geochemical measurements were addressed to more than one objective. One was to update a GIS of the co-seismic effects (associated to the earthquakes with magnitude greater than ML=5.0 and surveyed by our INGV EmerGeo Working Group) and their spatial and geometrical parameters in the local geological framework. More than 400 observation sites (fractures mainly) have been detected in an area of ~ 900 km2, part of which coupled with geochemical measurements in soils (fluxes and concentrations). Most of the surface effects have been observed also as regards the presence/absence at surface of deep fluids uprising (hot water, gas pools/fluxes, vapours, etc….) along and close to the previously mapped active faults (INGV Catalogue of Strong Historical earthquakes). Geochemical measurements in soils are very powerful to discriminate the numerous local surface effects (landslides, differential compaction, rock falling, etc) with respect to the real signatures of the expression at surface of the activated seismogenic segment. For earthquakes of moderate magnitude, such as the L’Aquila 2009 event, where the superficial effects could be absent or not evident, our geochemical method demonstrated to be strategic and potentially applicable in other worldwide seismic areas. Most ruptures with a structural significance have been observed along the Paganica Fault (elongated NW-SE); also the Bazzano and Monticchio-Fossa faults have been geochemically analysed; we searched the different behaviour of these structures as a whole, each having a different tectonic role (passive, active, transfer, crossing point, etc.), in determining the degassing observed at surface. The results highlight the maximum geochemical anomalies just along a minor anti-apenninic NE-SW transverse lineament; here, CO2 (up to 2000 [gm-2day-1]) and CH4 (up to 300 [gm-2day-1] anomalous fluxes were found soon after the main shock, remaining anomalous in the following months, but with lower values. Furthermore, just in correspondence of this lineament highest values of radon (up to 40.000 Bq/m3) were found. The transects perpendicular to the Paganica Fault clearly highlighted the role of the main fracture at surface (masked in few days) as preferential pathway for gases escaping from depth, as revealed by geochemical methods. The measured values are in any case not dangerous for the people’s health and minimise the problem of CO2-CH4 burst or explosions during strong earthquakes when these gases are stored naturally underground (km), as under these activated faults (as showed by the deep wells drilled in the area). Finally, the soundest sites to install 3 continuous monitoring stations, measuring the CO2 fluxes, were selected and the stations installed (Paganica, Bazzano and S. Gregorio sites) in cooperation with colleagues coming from the INGV geochemical department of Palermo (Sicily, southern Italy). The considered geochemical methods could be exploited along other faults in Italy and abroad by performing pre-main shock geochemical surveys to i) highlight earthquake preparation discovering anomalous degassing; ii) draw a picture of fault degassing before strong seismic events and, later, during a seismic sequence; iii) to highlight transverse lineaments among main fault segments, adding information where geo-structural expressions at surface are hidden.

Description: Published

Description: Damascus-Syria

Description: 2.4. TTC - Laboratori di geochimica dei fluidi

Description: open

Description: The 2009-2010 L'Aquila seismic sequence is still slightly occurring along the central Apenninic Belt (August 2010), spanning more than one year period. The main- shock (Mw 6.3) occurred on April 6th at 1:32 (UTC). The earthquake was destructive and caused among 300 casualties. The hypocenter has been located at 42.35°N, 13.38° at a depth of around 10 km. The main shock was preceded by a long seismic sequence starting several months before (i.e., March, 30, 2009 with Mw 4.1; April, 5 with Mw 3.9 and Mw 3.5, a few hours before the main shock). A lot of evidences stress the role of deep fluids porepressure evolution – possibly CO2 or brines - as occurred in the past, along seismically activated segments in Apennines. Our geochemical group started to survey the seismically activated area soon after the main-shock, by sampling around 1000 soil gas points and around 80 groundwater points (springs and wells, sampled on monthly basis still ongoing), to help in understanding the activated fault segments geometry and behaviour, as well as leakage patterns at surface (CO2, CH4, Radon and other geogas as He, H2, N2, H2S, O2, etc...), in the main sector of the activated seismic sequence, not far from a deep natural CO2 reservoir underground (termomethamorphic CO2 from carbonate diagenesis), degassing at surface only over the Cotilia-Canetra area, 20 km NW from the seismically activated area. The work highlighted that geochemical measurements on soils are very powerful to discriminate the activated seismogenic segments at surface, their jointing belt, as well as co-seismic depocenter of deformation. Mostly where the measured “threshold” magnitude of earthquakes (around 6), involve that the superficial effects could be absent or masked, our geochemical method demonstrated to be strategic, and we wish to use these methods in CO2 analogues/CO2 reservoir studies abroad, after done in Weyburn. The highlighted geochemical -slight but clear- anomalies are, in any case, not dangerous for the human health and keep away the fear around the CO2-CH4 bursts or explosions during strong earthquakes, as the L'Aquila one, when these gases are stored naturally/industrially underground in the vicinity (1-2 km deep). These findings are not new for these kind of Italian seismically activated faults and are very useful for the CO2- CH4 geological storage public acceptance: not necessarily (rarely or never) these geogas escape abruptly from underground along strongly activated faults.

Description: Published

Description: 4067-4075

Description: 4.5. Studi sul degassamento naturale e sui gas petroliferi

Description: N/A or not JCR

Description: reserved