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Horizontal to Vertical Spectral Ratio (HVSR) Measurements in the Mirandola anticline area (Northern Italy) (2018)

Tarabusi, Gabriele ; Caputo, Riccardo

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In: Supplement to: Tarabusi, Gabriele; Caputo, Riccardo (2017): The use of HVSR measurements for investigating buried tectonic structures: the Mirandola anticline, Northern Italy, as a case study. International Journal of Earth Sciences, 106(1), 341-353, https://doi.org/10.1007/s00531-016-1322-3

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Publication Date: 2023-01-13

Description: The Mirandola anticline represents a buried fault-propagation fold which has been growing during Quaternary due to the seismogenic activity of a blind segment belonging to the broader Ferrara Arc. The last reactivation occurred during the May 2012 Emilia sequence. In correspondence with this structure, the thickness of the marine and continental deposits of the Po Plain foredeep is particularly reduced. In order to better define the shallow geometry of this tectonic structure, and hence its recent activity, we investigated in a depth range which is intermediate between the surficial morphological observations and seismic profiles information. In particular, we carried out numerous passive seismic measurements (single-station microtremor) for obtaining the horizontal-to-vertical spectral ratio. The results of a combined analysis of the peak frequency and its amplitude nicely fit the available geological information, suggesting that this low-cost geophysical technique could be successfully applied in other sectors of wide morphologically flat alluvial plains to investigate blind and completely buried potential seismogenic structures. The complete dataset of 131 measurements, with HVSR curve in jpg format and peak frequency and amplitude of the ratio H/V values, is here provided.

Keywords: Amplitude; Event label; Frequency; Latitude of event; Longitude of event; Mirandola_Anticline_H001; Mirandola_Anticline_H002; Mirandola_Anticline_H003; Mirandola_Anticline_H004; Mirandola_Anticline_H005; Mirandola_Anticline_H006; Mirandola_Anticline_H007; Mirandola_Anticline_H008; Mirandola_Anticline_H009; Mirandola_Anticline_H010; Mirandola_Anticline_H011; Mirandola_Anticline_H012; Mirandola_Anticline_H013; Mirandola_Anticline_H014; Mirandola_Anticline_H015; Mirandola_Anticline_H016; Mirandola_Anticline_H017; Mirandola_Anticline_H018; Mirandola_Anticline_H019; Mirandola_Anticline_H020; Mirandola_Anticline_H021; Mirandola_Anticline_H022; Mirandola_Anticline_H024; Mirandola_Anticline_H025; Mirandola_Anticline_H026; Mirandola_Anticline_H027; Mirandola_Anticline_H028; Mirandola_Anticline_H029; Mirandola_Anticline_H030; Mirandola_Anticline_H031; Mirandola_Anticline_H032; Mirandola_Anticline_H033; Mirandola_Anticline_H034; Mirandola_Anticline_H035; Mirandola_Anticline_H036; Mirandola_Anticline_H037; Mirandola_Anticline_H038; Mirandola_Anticline_H039; Mirandola_Anticline_H040; Mirandola_Anticline_H041; Mirandola_Anticline_H042; Mirandola_Anticline_H043; Mirandola_Anticline_H044; Mirandola_Anticline_H045; Mirandola_Anticline_H046; Mirandola_Anticline_H047; Mirandola_Anticline_H048; Mirandola_Anticline_H049; Mirandola_Anticline_H050; Mirandola_Anticline_H051; Mirandola_Anticline_H052; Mirandola_Anticline_H053; Mirandola_Anticline_H054; Mirandola_Anticline_H055; Mirandola_Anticline_H056; Mirandola_Anticline_H057; Mirandola_Anticline_H058; Mirandola_Anticline_H059; Mirandola_Anticline_H062; Mirandola_Anticline_H064; Mirandola_Anticline_H065; Mirandola_Anticline_H066; Mirandola_Anticline_H067; Mirandola_Anticline_H068; Mirandola_Anticline_H069; Mirandola_Anticline_H070; Mirandola_Anticline_H071; Mirandola_Anticline_H072; Mirandola_Anticline_H073; Mirandola_Anticline_H074; Mirandola_Anticline_H075; Mirandola_Anticline_H076; Mirandola_Anticline_H077; Mirandola_Anticline_H078; Mirandola_Anticline_H079; Mirandola_Anticline_H080; Mirandola_Anticline_H081; Mirandola_Anticline_H082; Mirandola_Anticline_H083; Mirandola_Anticline_H084; Mirandola_Anticline_H085; Mirandola_Anticline_H086; Mirandola_Anticline_H087; Mirandola_Anticline_H089; Mirandola_Anticline_H090; Mirandola_Anticline_H091; Mirandola_Anticline_H092; Mirandola_Anticline_H093; Mirandola_Anticline_H094; Mirandola_Anticline_H095; Mirandola_Anticline_H096; Mirandola_Anticline_H097; Mirandola_Anticline_H098; Mirandola_Anticline_H099; Mirandola_Anticline_H100; Mirandola_Anticline_H101; Mirandola_Anticline_H102; Mirandola_Anticline_H103; Mirandola_Anticline_H104; Mirandola_Anticline_H105; Mirandola_Anticline_H106; Mirandola_Anticline_H107; Mirandola_Anticline_H108; Mirandola_Anticline_H109; Mirandola_Anticline_H110; Mirandola_Anticline_H111; Mirandola_Anticline_H112; Mirandola_Anticline_H113; Mirandola_Anticline_H114; Mirandola_Anticline_H115; Mirandola_Anticline_H116; Mirandola_Anticline_H117; Mirandola_Anticline_H118; Mirandola_Anticline_H119; Mirandola_Anticline_H120; Mirandola_Anticline_H121; Mirandola_Anticline_H122; Mirandola_Anticline_H123; Mirandola_Anticline_H124; Mirandola_Anticline_H125; Mirandola_Anticline_H126; Mirandola_Anticline_H127; Mirandola_Anticline_H128; Mirandola_Anticline_H129; Mirandola_Anticline_H130; Mirandola_Anticline_H131; Mirandola_Anticline_H132; Mirandola_Anticline_H133; Mirandola_Anticline_H134; Mirandola_Anticline_H135; Mirandola_Anticline_H136; Northern Italy; Station label; TROMINO; Uniform resource locator/link to image

Type: Dataset

Format: text/tab-separated-values, 524 data points

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Evolution of orthogonal sets of coeval extension joints (1995)

Caputo, Riccardo

Oxford, UK : Blackwell Publishing Ltd

Terra nova 7 (1995), S. 0

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ISSN: 1365-3121

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: The formation of two orthogonal sets of extension joints either crossing or abutting each other is a typical product of brittle deformation. Such systems of joints, with the two joint sets being geologically coeval, have been called a fracture grid-lock. The two sets are of common genesis and thus a unique remote stress field can be inferred. This interpretation causes some perplexity if the two joint sets are purely extension fractures and formed perpendicular to the least principal stress. In the present paper a conceptual model to explain the origin and the evolution of such systems is proposed. In a volume of rock undergoing a tensional and uniform remote stress state, caused for example by a tectonic regime, two horizontal and negative (i.e. tensional) stress rates are assumed to exist. When the tensile strength of the rock is locally reached, failure occurs perpendicular to the least principal stress. Then, that direction locally experiences a positive stress drop due to the stress release. For this reason, the stress field, retaining the same principal directions, is locally distorted by a swap between the σ3 and the σ2 components in a volume of rock surrounding the fracture. As a consequence of the persisting remote stress rates, when elastic failure conditions are newly accumulated, a second fracture forms and propagates perpendicular to the previous one. Repeated failure events, stress-drops and stress swaps eventually generate a fracture grid-lock. The whole process is also described with a simplified analytical model by applying elasticity theory.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-3121.1995.tb00549.x

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The North Aegean region: a tectonic paradox? (1994)

Pavlides, Spyros ; Caputo, Riccardo

Oxford, UK : Blackwell Publishing Ltd

Terra nova 6 (1994), S. 0

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ISSN: 1365-3121

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences

Notes: In the past two decades, several publications have been presented concerning the recent and active fault geometry, kinematics and geodynamics of the Aegean Region and particularly of the northern sector. Data and results are often contradictory and because of the complexity of the area most hypotheses and models should be considered carefully.The right-lateral movement of the North Anatolia Fault continues into some branches of the North Aegean fault system. There, strike-slip motion along NE–SW trending faults coexists with dip-slip E–W trending faults in the frame of an extensional regime related to N–S crustal stretching.If we take into account the geodynamic environment of the region, several mechanical problems arise. To the east, the Aegean is compressed by the westward convergence of Anatolia, while to the south and west along the Hellenic Arc, a hemiradial compression occurs due to subduction. Although the North Anatolia–North Aegean Trough fault system resembles a restraining bend, the whole area is in fact affected by pure extension and local transtension, along NE–SW trending structures. Accordingly, the major paradox of the area and especially in the western sector (fault termination?) is the occurrence of extension where compression should regionally, or at least locally, predominate.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-3121.1994.tb00631.x

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Evolution of orthogonal sets of coeval extension joints (1995)

Caputo, Riccardo

Wiley

In: Terra Nova. 1995; 7(5): 479-490. Published 1995 Sep 01. doi: 10.1111/j.1365-3121.1995.tb00549.x.

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Publication Date: 1995-09-01

Print ISSN: 0954-4879

Electronic ISSN: 1365-3121

Topics: Geosciences

Published by Wiley

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Mass distribution and moments of inertia in the outer shells of the Earth (2012)

Michele Caputo, Riccardo Caputo

Wiley

In: Terra Nova

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Publication Date: 2012-09-16

Description: Terra Nova, 00, 1–10, 2012 Abstract Different mass distributions within the lithosphere and the sub-lithospheric mantle have been considered here to calculate the moment of inertia of the outer shell of the Earth relative to many different axes. In particular, we seek for the maximum moment of inertia, MMI, which represents the theoretical rotation axis that the outer shell of the Earth should attain for maintaining equilibrium. For the present-day distribution of mass at depth, we consider the most updated crustal, lithospheric and sub-lithospheric models satisfying general geological and geophysical laws. When considering only the lithospheric shell, as if it were fully independent from the sub-lithospheric mantle (i.e. totally decoupled), our numerical results show the complete lack of equilibrium in terms of moment of inertia with respect to the present-day rotation axis. In further calculations, we also included the sub-lithospheric mantle assuming different density values as well as different compensation depths. Among the numerous tests, the mass distribution models showing theoretical axes of rotation closest to the present-day one are those obtained with a compensation depth of 400 km. The possible implications of these results in terms of westward plates drift and depth of possible decoupling layers within the mantle are discussed.

Print ISSN: 0954-4879

Electronic ISSN: 1365-3121

Topics: Geosciences

Published by Wiley

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