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Long-term strain oscillations related to the hydrological interaction between aquifers in intra-mountain basins: A case study from Apennines chain (Italy) (2018)

Devoti, Roberto ; Riguzzi, Federica ; Cinti, Francesca Romana ; [et al.]

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Publication Date: 2019-03-26

Description: We analyze the multiyear strain cycle of a network of continuous GPS stations in the L’Aquila intra-mountain basin in Central Apennines, Italy. The basin is bounded by two aquifers (Nuria-Velino and Gran Sasso) hosted in two tectonically active mountain ranges. All stations show coherent displacements, mostly in the horizontal plane and orthogonal to the normal fault zones of the Apennine mountain range. The displacement repeats back and forth, roughly every 4–5 years with elongation up to 6 mm. The deformation occurs in the region bounded by the two aquifers and the displacement amplitude decreases with distance as predicted by two tensile sources acting in an elastic medium. We interpret this type of deformation as induced by the opening of pre-existing fractures related to two different fault systems as a response to hydrostatic pressure variations. The strain cycle follows the average multiyear rainfall cycle and foresees a dilatation phase during high rainy seasons and a contraction during drier periods. The estimated depth of the equivalent tensile sources ranges from 1.2 to 1.5 km affecting stations at distances up to 20 km away. GPS data show the cumulated movement induced by the two nearby aquifers and suggest a mutual interaction in the elastic space related to the different average annual rainfall and effective infiltration. We fit two tensile sources located along the main faults affecting the aquifers. The eastern source corresponds to the major active fault system affecting the Gran Sasso Range, while the western one includes the sub-parallel active faults of the Mt. Ocre in the Nuria-Velino Range, where carbonate rocks show a higher structural permeability and effective infiltration. These fault systems affect Jurassic-Miocene limestones and dolomites inducing parallel fracturation style of the rock matrix and favoring a strong anisotropy allowing a prevalent lateral expansion as a reaction to pore pressure variations. The recorded hydrological signal may hamper other geophysical signals in GPS time series, thus the measure of tectonic strains requires a careful mapping and modeling of major aquifers.

Description: Published

Description: 1-12

Description: 2T. Deformazione crostale attiva

Description: JCR Journal

Keywords: strain ; aquifer and multi-aquifer ; GPS time series ; active faults ; intra-mountain basins ; Apennines

Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)

Type: article

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Geodynamics, geophysical and geochemical observations, and the role of CO2 degassing in the Apennines (2022)

Di Luccio, Francesca ; Palano, Mimmo ; Chiodini, Giovanni ; [et al.]

Elsevier

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Publication Date: 2022-12-01

Description: An accurate survey of old and new datasets allowed us to probe the nature and role of fluids in the seismogenic processes of the Apennines mountain range in Italy. New datasets include the 1985–2021 instrumented seismicity catalog, the computed seismogenic thickness, and geodetic velocities and strains, whereas data from the literature comprise focal mechanism solutions, CO2 release, Moho depth, tomographic seismic velocities, heat flow and Bouguer gravity anomalies. Most of the inspected datasets highlight differences between the western and eastern domains of the Apennines, while the transition zone is marked by high geodetic strain, prevailing uplift at the surface and high seismic release, and spatially corresponds with the overlapping Tyrrhenian and Adriatic Mohos. Published tomographic models suggest the presence of a large hot asthenospheric mantle wedge which intrudes beneath the western side of the Apennines and disappears at the southern tip of the southern Apennines. This wedge modulates the thermal structure and rheology of the overlying crust as well as the melting of carbonate-rich sediments of the subducting Adriatic lithosphere. As a result, CO2-rich fluids of mantle-origin have been recognized in association with the occurrence of destructive seismic sequences in the Apennines. The stretched western domain of the Apennines is characterized by a broad pattern of emissions from CO2-rich fluids that vanishes beneath the axial belt of the chain, where fluids are instead trapped within crustal overpressurized reservoirs, favoring their involvement in the evolution of destructive seismic sequences in that region. In the Apennines, areas with high mantle He are associated with different degrees of metasomatism of the mantle wedge from north to south. Beneath the chain, the thickness and permeability of the crust control the formation of overpressurized fluid zones at depth and the seismicity is favored by extensional faults that act as high permeability pathways. This multidisciplinary study aims to contribute to our understanding of the fluid-related mechanisms of earthquake preparation, nucleation and evolution encouraging a multiparametric monitoring system of different geophysical and geochemical observables that could lead the creation of a data-constrained and reliable conceptual model of the role of fluids in the preparatory phase of earthquakes in the Apennines.

Description: The INGV Earthquake Department Strategic Project FURTHER “The role of FlUids in the pReparaTory pHase of EaRthquakes in Southern Apennines”

Description: Published

Description: 104236

Description: 1T. Struttura della Terra