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G. De Natale C. Troise F. Pingue P. De Gori C. Chiarabba 《Mineralogy and Petrology》2001,73(1-3):5-22
Summary We review recently obtained results about the velocity structure of the Somma-Vesuvius (Southern Italy) volcanic complex
and present an interpretation of structural features, both at local and regional scale, and of the local seismicity. The local
structure of Somma-Vesuvius is reviewed, referring to three depth ranges; i.e. shallow (0–5 km), intermediate (5–15 km) and
deep (from 15 km to the upper mantle). The shallow velocity structure is inferred by the joint inversion of shot and local
earthquake arrival time data. The main feature pointed out by this inversion is a high-velocity anomaly at the crater axis
extending down to a depth of about 5 km. This anomaly can be explained with the presence of residual magma crystallised in
the shallow conduits, which accumulated during the last eruptive cycles. The local seismicity is strongly clustered around
this anomaly, due to the focusing effect of the rigidity contrast. The space-time seismicity pattern at Somma-Vesuvius is
the result of the superposition of background seismicity, mainly due to gravitational instability of the volcanic edifice
and to small external stress perturbations, with intense episodic earthquake swarms possibly due to magmatic or hydrothermal
activity into the shallow system. The velocity structure in the 10–15 km depth range is characterized by the presence of a
low-velocity layer, which has been independently confirmed by multi-channel seismic reflection data and P-Sv conversions from
teleseismic waveforms. The study of the deep structure was performed by regional tomography with teleseisms; it confirmed
the presence of a low-velocity anomaly underneath the volcano, which appears to have roots at greater depths. The regional
structure between the Thyrrenian and the Adriatic sea has been inferred by tomographic inversion of teleseismic arrival times.
The main result from this study which is very important for geodynamic interpretations is the first evidence for a continuous
subducting slab under the Apennines, in an area where previous models hypothesized a slab window.
Received March 3, 2000 revised version accepted July 4, 2001 相似文献
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M. Piochi C. R. J. Kilburn M. A. Di Vito A. Mormone A. Tramelli C. Troise G. De Natale 《International Journal of Earth Sciences》2014,103(2):401-421
The Campi Flegrei caldera in southern Italy is one of the greatest geohazard areas on Earth. Evidence of an active magmatic and geothermal system is provided by ongoing ground uplift, with volcano-tectonic and long-period (LP) seismicity, the persistent degassing of ~1500 tonnes of CO2 per day, the presence of hot fumaroles at temperatures of 90–150 °C, brine-rich aquifers (with total dissolved solids up to 33 g l?1) and high thermal gradients in the crust (with temperatures reaching 420 °C at 3,050 m b.s.l.). Since the 1940s, more than 100 exploratory boreholes have been drilled in the area to depths of 80–3,100 m by the Azienda Geologica Italiana Petroli (AGIP) and the Società Anonima Forze Endogene Napoletane (SAFEN). To date, however, no systematic reanalysis of the drilling data has been carried out, and the buried volcanic structure has not been updated using the most recent scientific results and previous findings. By integrating unpublished data from the AGIP and SAFEN reports with published information from geological, volcanological, petrological, petrophysical and geophysical studies, this paper presents an improved picture of the Campi Flegrei caldera that will be useful for volcanic hazard assessment and mitigation in the Naples area and for future research planning. The results suggest that intra-caldera activity has been influenced by how the magmatic system at depths greater than about 4 km has determined the transfer of magma, volatiles, and heat to the overlying geothermal system and, ultimately, to the surface. In particular, intriguing is that the most volcanically active central-eastern sector of the caldera, which is subject to intense bradyseismic ground movement and gas emission, coincides with a structurally delimited subsurface rock volume characterized by an uprising of the 100 °C isotherm, a deep water supply to the shallower aquifer, the early disappearance of secondary calcite, LP seismicity and high seismic S-wave attenuation. In this area, we also document evidence of repeated injection at depths of c. 1.5–3.0 km of isolated and small-volume batches of magma, where occurred their crystallization and degassing. Shallow intrusions and degassing of magma are thus identified as two of the key processes that drive unrest in Campi Flegrei. 相似文献
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Giuseppe De?Natale Igor?Kuznetzov Tatiana?Kronrod Antonella?PeresanEmail author Angela?Saraò Claudia?Troise Giuliano F.?Panza 《Pure and Applied Geophysics》2004,161(1):123-144
We analyse the seismic catalogue of the local earthquakes which occurred at Somma-Vesuvius volcano in the past three decades (1972–2000). The seismicity in this period can be described as composed of a background level, characterised by a low and rather uniform rate of energy release and by sporadic periods of increased seismic activity. Such relatively intense seismicity periods are characterised by energy rates and magnitudes progressively increasing in the critical periods. The analysis of the b value in the whole period evidences a well-defined pattern, with values of b progressively decreasing, from about 1.8 at the beginning of the considered period, to about 1.0 at present. This steady variation indicates an increasing dynamics in the volcanic system. Within this general trend it is possible to identify a substructure in the time sequence of the seismic events, formed by the alternating episodes of quiescence and activity. The analysis of the source moment tensor of the largest earthquakes shows that the processes at the seismic source are generally not consistent with simple double-couples, but that they are compatible with isotropic components, mostly indicating volumetric expansion. These components are shown to be statistically significant for most of the analysed events. Such focal mechanisms can be interpreted as the effect of explosion phenomena, possibly related to volatile exsolution from the crystallising magma. The availability of a reduced amount of high quality data necessary for the inversion of the source moment tensor, the still limited period of systematic observation of Vesuvius micro-earthquakes and, above all, the absence of eruptive events during such interval of time, cannot obviously permit the outlining of any formal premonitory signal. Nevertheless, the analysis reported in this paper indicates a progressively evolving dynamics, characterised by a generally increasing trend in the seismic activity in the volcanic system and by a significant volumetric component of recent major events, thus posing serious concern for a future evolution towards eruptive activity. 相似文献
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S. Vinciguerra C. Trovato P.G. Meredith P.M. Benson C. Troise G. De Natale 《Pure and Applied Geophysics》2006,163(10):2205-2221
We report laboratory measurements of P- and S-wave velocities on samples of tuff from Campi Flegrei (Italy), and a new tomographic
velocity map of the Campi Flegrei caldera. Laboratory measurements were made in a hydrostatic pressure vessel during both
increasing and decreasing effective pressure cycles. Selected samples were also thermally stressed at temperatures up to 600°C
to induce thermal crack damage. Acoustic emission output was recorded throughout each thermal stressing experiment, and velocities
were measured after thermal stressing. Laboratory P- and S-wave velocities are initially low for the tuff, which has an initial
porosity of ~45%, but both increase by between 25 and 50% over the effective pressure range of 5 to 80 MPa, corresponding
to a decrease of porosity of ~70%. Marked velocity hysteresis, due to inelastic damage processes, is also observed in samples
subjected to a pressurization-depressurization cycle. Tomographic seismic velocity distributions obtained from field recordings
are in general agreement with the laboratory measurements. Integration of the laboratory ultrasonic and seismic tomography
data indicates that the tuffs of the Campi Flegrei caldera can be water or gas saturated, and shows that inelastic pore collapse
and cracking produced by mechanical and thermal stress can significantly change the velocity properties of Campi Flegrei tuffs
at depth. These changes need to be taken into account in accurately interpreting the crustal structure from tomographic data. 相似文献
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We present here a consistent model, which explains the mechanisms of unrest phenomena at Campi Flegrei (Italy), both at short-term (years) and at secular scales. The model consists basically of two effects: the first one is related to the elastic response of the shallow crust to increasing pressure within a shallow magma chamber; the second involves the fluid-dynamics of shallow aquifers in response to increasing pressure and/or temperature at depth. The most important roles in the proposed model are played by the effect of lateral stress–strain discontinuities marking the inner caldera borders and by the response of the geothermal system to the increase of pressure and/or temperature coming from the magma chamber. The model takes into account most results of recent research, and it is able to explain in a unitary way most of geophysical observations recently collected at Campi Flegrei. Some new results, presented in this paper, explain the mechanism of generation of seismicity in terms of Coulomb stress changes, and the difference between secular and short-term deformations, in terms of the non linear effect of the bordering discontinuities. The coupled effects of magma chamber stresses with the dynamics of shallow fluids provide results for a semi-quantitative interpretation of observed ground deformation, seismicity and of their time evolution. The model has very important implications for the hazard assessment during unrest phenomena. It represents, for the part involving the fluid-dynamical response, the ideal continuation of the basic, fundamental models and intuitions of Oliveri del Castillo and coworkers (Oliveri del Castillo, A., Quagliariello, M.T., 1969. Sulla genesi del bradisimo flegro. Atti Associazione Geofisica Italiana, 18th Congress, Napoli, pp. 557–594; Casterano, L., Oliveri del Castillo, A., Quagliariello, M.T., 1976. Hydromdynamics and geodynamics in the Phlegraean Fields area of Italy. Nature, 264, 161–154). 相似文献
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