Your search keyword '"Camanni, Giovanni"' showing total 31 results

1. Fault-controlled saddle dolomitization during the late Triassic Pangea breakup in the southern Adria domain (Southern Italy)

Author

Diamanti, Renato, Awais, Muhammad, Camanni, Giovanni, D'Antonio, Massimo, Della Porta, Giovanna, Di Renzo, Valeria, Graziano, Sossio Fabio, Iannace, Alessandro, Kylander-Clark, Andrew, Vitale, Enza, and Vitale, Stefano

Published

2025

2. 3D geometry and displacement transfer of an oblique relay zone on outcropping normal faults

Author

Camanni, Giovanni, Freda, Giovanni, Delogkos, Efstratios, Nicol, Andrew, and Childs, Conrad

Published

2023

3. The role of antithetic faults in transferring displacement across contractional relay zones on normal faults

Author

Camanni, Giovanni, Childs, Conrad, Delogkos, Efstratios, Roche, Vincent, Manzocchi, Tom, and Walsh, John

Published

2023

4. Fault systems in the offshore sector of the Campi Flegrei caldera (southern Italy): Implications for nested caldera structure, resurgent dome, and volcano-tectonic evolution

Author

Natale, Jacopo, Camanni, Giovanni, Ferranti, Luigi, Isaia, Roberto, Sacchi, Marco, Spiess, Volkhard, Steinmann, Lena, and Vitale, Stefano

Published

2022

5. A gravitational origin for volcano-tectonic faults in the Campi Flegrei caldera (southern Italy) inferred from detailed field observations

Author

Diamanti, Renato, Camanni, Giovanni, Natale, Jacopo, and Vitale, Stefano

Published

2022

6. The significance of fault reactivation on the Wilson cycle undergone by the northern South China Sea area in the last 60 Myr

Author

Camanni, Giovanni and Ye, Qing

Published

2022

7. Fracture density variations within a reservoir-scale normal fault zone: A case study from shallow-water carbonates of southern Italy

Author

Camanni, Giovanni, Vinci, Francesco, Tavani, Stefano, Ferrandino, Valeria, Mazzoli, Stefano, Corradetti, Amerigo, Parente, Mariano, and Iannace, Alessandro

Published

2021

8. Variability in the three-dimensional geometry of segmented normal fault surfaces

Author

Roche, Vincent, Camanni, Giovanni, Childs, Conrad, Manzocchi, Tom, Walsh, John, Conneally, John, Saqab, Muhammad Mudasar, and Delogkos, Efstratios

Published

2021

9. The 3D structure of a normal fault from multiple outcrop observations

Author

Delogkos, Efstratios, Manzocchi, Tom, Childs, Conrad, Camanni, Giovanni, and Roche, Vincent

Published

2020

10. The Mountain Front Flexure in the Lurestan region of the Zagros belt: Crustal architecture and role of structural inheritances

Author

Tavani, Stefano, Camanni, Giovanni, Nappo, Michele, Snidero, Marco, Ascione, Alessandra, Valente, Ettore, Gharabeigli, Gholamreza, Morsalnejad, Davoud, and Mazzoli, Stefano

Published

2020

11. The three-dimensional geometry of relay zones within segmented normal faults

Author

Camanni, Giovanni, Roche, Vincent, Childs, Conrad, Manzocchi, Tom, Walsh, John, Conneally, John, Saqab, Muhammad Mudasar, and Delogkos, Efstratios

Published

2019

12. The Late Cretaceous tectonic evolution of the South China Sea area: An overview, and new perspectives from 3D seismic reflection data

Author

Ye, Qing, Mei, Lianfu, Shi, Hesheng, Camanni, Giovanni, Shu, Yu, Wu, Jing, Yu, Lu, Deng, Peng, and Li, Gang

Published

2018

13. A low-angle normal fault and basement structures within the Enping Sag, Pearl River Mouth Basin: Insights into late Mesozoic to early Cenozoic tectonic evolution of the South China Sea area

Author

Ye, Qing, Mei, Lianfu, Shi, Hesheng, Shu, Yu, Camanni, Giovanni, and Wu, Jing

Published

2018

14. The deep structure of south-central Taiwan illuminated by seismic tomography and earthquake hypocenter data

Author

Camanni, Giovanni, Alvarez-Marron, Joaquina, Brown, Dennis, Ayala, Concepcion, Wu, Yih-Min, and Hsieh, Hsien-Hsiang

Published

2016

15. The complex 3D multi-segmented rupture of the 2014 Mw 6.2 Northern Nagano Earthquake revealed by high-precision aftershock locations

Author

Muzellec, Titouan, De Landro, Grazia, Camanni, Giovanni, Adinolfi, Guido Maria, and Zollo, Aldo

Abstract

Recent estimates of the rupture scenarios of moderate-to-large earthquakes highlights the need of incorporating segmented fault surfaces into seismic hazard models rather than individual, planar ones. The 2014 Northern Nagano earthquake sequence provides an opportunity to rethink the fault system geometrical complexities of the Itoigawa-Shizuoka tectonic line, one of the most inland active faults in Japan, and their impact on the fault rupture nucleation and development. For this study we used continuous records of 37 seismic stations to detect and locate 2500 events that occurred from 1st October 2014 to 31 December 2014. By refining the automatic arrival time picks, based on the cross-correlation and the hierarchical clustering, we relocated the earthquake hypocenters with the double-difference locationand a three-dimensional (3D) velocity model. We obtained a high-quality earthquake location catalog and the composite focal mechanisms which served for constraining the 3D geometry of the segmented fault system. We found that the early aftershocks are distributed along two sub-parallel, NNE-SSW striking, en-echelon, left-stepping fault segments and analyses on the spatio-temporal evolution of fault activation suggest that the rupture propagates in a clockwise direction, involving first the shallow northern portion of the segmented fault system, then the deeper northern portion of it, and finally the deeper and the shallower parts of the southern portion. Results suggest that a relationship exists between the rupture mechanism and the 3D segmented fault geometry. This relationship between initial structure of the segmented fault controls the earthquake rupture becomes crucial to assess reliable scenarios in seismic hazard., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published

2023

16. 3‐D Structure and Development of a Metamorphic Core Complex in the Northern South China Sea Rifted Margin.

Author

Ye, Qing, Mei, Lianfu, Jiang, Dapeng, Xu, Xinming, Delogkos, Efstratios, Zhang, Lili, and Camanni, Giovanni

Subjects

CRUST of the earth, METAMORPHIC rocks, DUCTILE fractures, STRAINS & stresses (Mechanics), SEISMOLOGY

Abstract

The 3‐D structure of continental metamorphic core complexes (MCCs) and their coevolution along with the associated extensional detachments are still not well understood. In this study, analysis of a newly acquired high‐resolution 3‐D seismic reflection volume reveals for the first time a well‐imaged MCC in the proximal northern South China Sea (SCS) rifted margin, the Kaiping MCC (KP MCC). These data provide a 3‐D view of the KP MCC and the associated KP detachment fault. The KP MCC is characterized by ascend of ductile midcrustal materials, and it is partially exhumed in the KP9 High. The KP detachment fault displays a domed low‐angle geometry, and is characterized by pronounced NS‐plunging corrugations, among which two megacorrugations of tens of kilometers are revealed. Evidence show that the KP MCC developed according to the classical rolling‐hinge model. A group of secondary normal faults and fractures, which are parallel to the axis of the KP MCC and offset the KP detachment surface at the crest of the MCC, developed in response to inelastic bending during progressive warping of the footwall. The migration of the domal seismic reflection layers provides a visual evidence for the kinematic process of the rolling‐hinge activity, during which the brittle‐ductile transition and the rolling hinge gradually migrate as the detachment fault slips. The origin of the KP MCC in the northern SCS margin is suggested to have been favored by the existence of a pre‐existing midcrustal ductile layer and basement structures within the upper brittle crust. Plain Language Summary: A metamorphic core complex (MCC) is an exposure of deep crust associated with extensional processes. Current understanding on MCCs is mainly derived from outcrop and geomorphic studies that only allow their exhumed part to be observed. A newly acquired 3‐D seismic reflection volume reveals a well‐imaged MCC, the Kaiping MCC (KP MCC), in the proximal northern South China Sea (SCS) rifted margin, permitting, for the first time, a detailed 3‐D examination of the MCC structure and its associated detachment fault. In this study, we present the 3‐D structure of the KP MCC, the geometry and kinematics of the associated KP detachment fault, and then we discuss the development and origin of the KP MCC. We propose that the KP MCC developed according to the rolling‐hinge model, with our data providing a visual evidence for the kinematic processes during which the brittle‐ductile transition and the rolling hinge gradually migrate as the detachment fault slips. We suggest that the origin of the KP MCC is favored by the existence of a pre‐existing midcrustal ductile layer and basement structures within the upper crust. Our study not only have implication for the SCS rifting but also advance understanding on the development and origin of MCCs. Key Points: A first imaged metamorphic core complex (MCC) in the proximal northern South China Sea rifted margin and its 3‐D structure is describedVisual evidence for the gradual migration of the brittle‐ductile transition and rolling hinge during the rolling‐hinge evolution of a MCCThe origin of the MCC was favored by a pre‐existing midcrustal ductile layer and basement structures within the upper crust [ABSTRACT FROM AUTHOR]

Published

2022

17. How the structural architecture of the Eurasian continental margin affects the structure, seismicity, and topography of the south central Taiwan fold-and-thrust belt

Author

Brown, Dennis, Alvarez-Marrón, Joaquina, Biete, Cristina, Kuo-Chen, Hao, Camanni, Giovanni, Ho, Chun-Wei, and Ministerio de Economía y Competitividad (España)

Subjects

Inheritance, Tectonics, Taiwan, Structure

Abstract

Studies of mountain belts worldwide show that along-strike changes are common in their foreland fold-and-thrust belts. These are typically caused by processes related to fault reactivation and/or fault focusing along changes in sedimentary sequences. The study of active orogens, like Taiwan, can also provide insights into how these processes influence transient features such as seismicity and topography. In this paper, we trace regional-scale features from the Eurasian continental margin in the Taiwan Strait into the south central Taiwan fold-and-thrust belt. We then present newly mapped surface geology, P wave velocity maps and sections, seismicity, and topography data to test the hypothesis of whether or not these regional-scale features of the margin are contributing to along-strike changes in structural style, and the distribution of seismicity and topography in this part of the Taiwan fold-and-thrust belt. These data show that the most important along-strike change takes place at the eastward prolongation of the upper part of the margin necking zone, where there is a causal link between fault reactivation, involvement of basement in the thrusting, concentration of seismicity, and the formation of high topography. On the area correlated with the necking zone, the strike-slip reactivation of east northeast striking extensional faults is causing sigmoidal offset of structures and topography along two main zones. Here basement is not involved in the thrusting; there is weak focusing of seismicity and localized development of topography. We also show that there are important differences in structure, seismicity, and topography between the margin shelf and its necking zone. ©2017. American Geophysical Union., D.B., J.A-M., and C.B. acknowledge funding provided by the Spanish Ministerio de Economia y Competividad grant CGL2013-43877-P. H.K-C. acknowledges funding by MOST 104-2628-M-008-005-MY3.

Published

2017

18. Layering and structural inheritance controls on fault zone structure in three dimensions: a case study from the northern Molasse Basin, Switzerland.

Author

Roche, Vincent, Childs, Conrad, Madritsch, Herfried, and Camanni, Giovanni

Subjects

MOLASSE, FAULT zones, YOUNG'S modulus, FOLDS (Geology), SEISMIC surveys

Abstract

Mechanical heterogeneity of a sedimentary sequence exerts a primary control on the geometry of fault zones and the proportion of offset accommodated by folding. The Wildensbuch Fault Zone in the Swiss Molasse Basin, with a maximum throw of 40 m, intersects a Mesozoic section containing a thick (120 m) clay-dominated unit (Opalinus Clay) over- and underlain by more competent limestone units. Interpretation of a 3D seismic reflection survey indicates that the fault zone formed by upward propagation of an east–west-trending basement structure, through the Mesozoic section, in response to NE–SW Miocene extension. This configuration formed an array of left-stepping normal fault segments above and below the Opalinus Clay. In cross-section a broad monoclinal fold is observed in the Opalinus Clay. Folding, however, is not ubiquitous and occurs in the Opalinus Clay where fault segments above and below are oblique to one another; where they are parallel the fault passes through the Opalinus Clay with little folding. These observations demonstrate that, even in strongly heterogeneous sequences, here a four-fold difference in both Young's modulus and cohesion between layers, the occurrence of folding may depend on the local relationship between fault geometry and applied stress field rather than rheological properties alone. [ABSTRACT FROM AUTHOR]

Published

2020

19. The structure of the south‐central Taiwan thrust belt

Author

Camanni, Giovanni, Brown, Dennis, 1958, Álvarez Marrón, Joaquina, Roca i Abella, Eduard, and Universitat de Barcelona. Facultat de Geologia

Subjects

Falles (Geologia), Tectonics, Faults (Geology), Structural geology, Taiwan, Geologia estructural, Geología estructural, Tectónica, Fallas (Geología), Ciències Experimentals i Matemàtiques, Tectònica

Abstract

[spa] La estructura de la cordillera de Taiwán se considera constituida por un sistema de cabalgamientos y pliegues desarrollados sobre un despegue basal con suave inclinación, situado en la cobertera sedimentara de la margen continental Euroasiática. Una cantidad creciente de datos de sismicidad y de geología de superficie, sin embargo, indican la existencia de actividad generalizada de fracturas en la corteza media e inferior y sugieren que los niveles de la corteza por debajo de la ubicación del despegue basal también están actualmente involucrados en la deformación. En esta tesis, nuevos datos de geología de superficie se combinaron con varios conjuntos de datos geofísicos disponibles para encontrar un modelo para la estructura de la parte sur-central de la cordillera de Taiwán. Los resultados de este trabajo indican que debajo de la parte interna de la área de estudio el desarrollo estructural de la cordillera de Taiwán esta controlado por fallas mayores con alta inclinación, que penetran hasta partes profundas de la corteza, y que están reactivando fallas preexistentes heredadas de la margen continental Euroasiática. Rocas de basamento están elevadas a lo largo de estas fallas y forman una culminación por debajo de las partes internas de la cordillera. Por debajo de el Coastal Plain y de las Western Foothills en la parte externa de la área de estudio, sin embargo, la mayor parte de la deformación parece estar teniendo lugar cerca de la interfaz basamento-cobertera, que está actuando como un amplio nivel de despegue basal y aún conserva la geometría extensional heredada de la margen continental Euroasiática., [eng] The Taiwan thrust belt is generally thought to develop above a shallow, through-going basal detachment confined to within the sedimentary cover of the Eurasian continental margin. A number of data sets, however, such as surface geology, earthquake hypocentre, and seismic tomography data among others, suggest that crustal levels below the interpreted location of the detachment are also currently being involved in the deformation. In this thesis, new surface geology data were combined with several available geophysical data sets to find a model for the structure of the south-central part of the thrust belt that takes into account deformation taking place at depth. Results of this thesis indicate that beneath the internal Hsuehshan and Central ranges the structural development of the south-central Taiwan thrust belt is controlled by steeply dipping and deep-penetrating faults that are currently inverting pre-existing basement faults inherited from the Eurasian continental margin. Basement rocks are uplifted along these faults to form a basement culmination in the interior of the thrust belt. Beneath the more external Coastal Plain and Western Foothills, however, most of the deformation appears to be taking place near the basement-cover interface, which is acting as an extensive level of detachment and still preserves the extensional geometry inherited from the Eurasian margin.

Published

2014

20. Structural styles of the Shuilikeng fault system in the central Taiwan mountain belt

Author

Camanni, Giovanni, Brown, Dennis, and Alvarez-Marrón, Joaquina

Abstract

The Shuilikeng fault system in the central Taiwan mountain belt forms the structural boundary between two different tectonostratigraphic zones: the Western Foothills to the W, and the Hsuehshan Range to the E. It comprises a steeply-dipping roughly north-striking transpressive fault zone with splays, folds and bifurcations linked to the main structure. The structural style of the Shuilikeng fault system changes from N to S; while to the N it is defined by diverging splay and non-cylindrical folds branching off the Shuilikeng fault, to the S its structure is dominated by east-striking right-lateral strike-slip faults in the Hsuehshan Range and by a rejoining splay with a composite kinematics in the Western Foothills. At the southernmost tip of the study area, the Shuilikeng fault is defined by a several hundred meters-wide high strain zone and the structural architecture of the Western Foothills is that of a regional anticlinorium branching off the Shuilikeng fault intensely folded and faulted along its limbs., G. Camanni acknowledges the grant JAE-Predoc (CSIC). This research was carried out with the aid of the grant MICINN: CGL2009-11843-BTE.

Published

2012

21. The structure of the central Taiwan mountain belt

Author

Brown, Dennis, Alvarez-Marrón, Joaquina, and Camanni, Giovanni

Subjects

Taiwan, trust belt, transpression

Abstract

The structure of the Taiwan mountain belt is thought to be that of an imbricate thrust and fold belt developed above a shallowly dipping basal detachment. In recent years, however, a growing amount of seismicity data from the internal part of the mountain belt indicates the existence of widespread fault activity in the middle and lower crust. Here, we present new geological mapping from the central part of Taiwan. We suggest that the foreland basin part of the Western Foothills comprises an imbricate thrust system that is structurally and kinematically linked to a basal detachment at between 7 and 10 km depth. To the east of the foreland basin, in the Hsuehshan Range, our data show the presence of major faults that are steeply dipping and which penetrate deep into the crust. A structural and kinematic model in which this part of the mountain belt forms a zone of transpression better fits the available data. Eastward, in the Central Range, deep water sediments appear to form an allochthon that is being overthrust by Mesozoic basement rocks. The involvement of Mesozoic basement in the deformation is suggestive of the reactivation of pre-existing basin-bounding faults, This research was carried out with the aid of grants by CSIC –Proyectos Intramurales 2006 3 01 010, and MICINN: CGL2009-11843-BTE.

Published

2012

22. Geology of the Fontane talc mineralization (Germanasca valley, Italian Western Alps).

Author

Cadoppi, Paola, Camanni, Giovanni, Balestro, Gianni, and Perrone, Gianluigi

Subjects

*TALC, *CARBONIFEROUS paleogeography

Abstract

The 1:5000 scale Geological Map of the Fontane talc mineralization (FTM) aims to give new information about the origin and geological structure of an important talc mineralization occurring in the axial sector of the Italian Western Alps. The FTM is hosted within a pre-Carboniferous polymetamorphic complex which was deformed and metamorphosed during both Variscan and Alpine orogenesis, and is part of the Dora-Maira continental crust. Field mapping and underground investigations highlight that the talc bodies (i) never crop out but occur at depth along a well-defined lithostratigraphic association between micaschist, marble and gneiss and (ii) were deformed during different Alpine-related deformation phases (i.e. D1, D2and D3syn-metamorphic phases and post-metamorphic extensional faulting). The here defined lithostratigraphic and structural characterization of talc bodies, is an input for further research into the geodynamic context of where talc forms and for new mineral exploration outside the mapped area. [ABSTRACT FROM AUTHOR]

Published

2016

23. Structural complexities in a foreland thrust belt inherited from the shelf-slope transition: Insights from the Alishan area of Taiwan.

Author

Alvarez-Marron, Joaquina, Brown, Dennis, Camanni, Giovanni, Wu, Yih-Min, and Kuo-Chen, Hao

Abstract

The Alishan area of Taiwan spans the transition from the platform with full thickness of the Eurasian continental margin in the north to the thinning crust of its slope in the south. This part of the foreland thrust and fold belt includes important along-strike changes in structure, stratigraphy, and seismic velocities. In this paper we present the results of new geological mapping from which we build geological cross sections both across and along the regional structural trend. Fault contour, stratigraphic cutoff, and branch line maps provide 3-D consistency between the cross sections. Minimum shortening is estimated to be ~15 km with displacement overall to the northwest. A P wave velocity model helps constrain the structure at depth by providing insight into the possible rock units that are present there. P wave velocities of ≥ 5.2 km/s point toward the presence of basement rocks in the shallow subsurface throughout much of the southeastern part of the area, forming a basement culmination. The changes in strike of thrusts and fold axial traces, the changing elevation of thrusts and stratigraphic contacts, and the growing importance of Middle Miocene sediments that take place from north to south are interpreted to be associated with a roughly northeast striking lateral structure coincident with the northern flank of this basement culmination. These transverse structures appear to be associated with the inversion of Eocene- and Miocene-age extensional faults along what was the shelf-slope transition in the Early Oligocene, uplifting the margin sediments and their higher P wave velocity basement during Pliocene-Pleistocene thrusting. [ABSTRACT FROM AUTHOR]

Published

2014

24. Basin inversion in central Taiwan and its importance for seismic hazard.

Author

Camanni, Giovanni, Chi-Hsuan Chen, Brown, Dennis, Alvarez-Marron, Joaquina, Yih-Min Wu, Hsi-An Chen, Hsin-Hua Huang, Hao-Tsu Chu, Mien-Ming Chen, and Chien-Hsin Chang

Subjects

*GEOLOGICAL basins, *EARTHQUAKE hazard analysis, *EARTHQUAKES, *EARTHQUAKE aftershocks, *P-waves (Seismology), *EOCENE Epoch

Abstract

On 27 March 2013, a 6.2 ML earthquake occurred at 19 km depth in eastern Nantou, central Taiwan. Over a 2 week period it was followed by more than 680 aftershocks that ranged to 5 ML. Most events occurred below the ~10-km-deep detachment fault predicted for this part of the mountain belt, coinciding with other precisely located hypocenters that indicate that much of the crust in this area is seismically active. We combine geological data with a three-dimensional (3-D) P-wave velocity model derived from local tomography and earthquake hypocenters to determine a model for the structure of central Taiwan. Much of the surface geology of the area comprises the uplifted Eocene rocks of the Hsuehshan Basin. The 3-D P-wave velocity model shows a shallowing of higher velocities across the Hsuehshan Basin and hypocenter data indicate that its western bounding fault is clearly defined by an eastward-dipping band of events that extends to >20 km depth. The eastern bounding fault is interpreted to coincide at depth with a cluster of events between 20 and 30 km depth. These data suggest that the preexisting, rift-related extensional faults of the Hsuehshan Basin are currently being reactivated and the basin is being inverted. We present hypocenter data from the Nantou sequence that corroborate this interpretation and show the importance of choosing the correct structural model when assessing seismic risk. [ABSTRACT FROM AUTHOR]

Published

2014

25. The Shuilikeng fault in the central Taiwan mountain belt.

Author

CAMANNI, GIOVANNI, BROWN, DENNIS, ALVAREZ-MARRON, JOAQUINA, YIH-MIN WU, and HSI-AN CHEN

Subjects

*GEOLOGIC faults, *OROGENIC belts, *MIOCENE Epoch, *FOOTHILLS, *EOCENE Epoch

Abstract

For over 200 km along strike the Shuilikeng fault of Taiwan separates Miocene rocks of the Western Foothills from the largely Eocene and Oligocene rocks of the Hsuehshan Range to the east. Despite its importance in the Taiwan mountain belt, the structure and kinematics of the Shuilikeng fault are not well known. Here, we present results from new geological mapping along 100 km of its strike length. At the surface, the Shuilikeng fault is a steeply east-dipping brittle fault with a series of splays and bifurcations. Along its southern part, it cuts an earlier fold and fault system. Outcrop kinematic data vary widely, from thrusting to strike-slip. The surface data are integrated with a relocated and collapsed seismicity database to interpret the fault location at depth. These data indicate that the Shuilikeng fault can be traced to greater than 20 km depth. Some 260 focal mechanisms from this dataset indicate that its kinematics is overall transpressive. From a regional perspective, we interpret the Shuilikeng fault to reactivate a pre-existing rift-related basin-bounding fault to the east of which rocks in the Hsuehshan Range are being exhumed. [ABSTRACT FROM AUTHOR]

Published

2014

26. Studying a Subsiding Urbanized Area from a Multidisciplinary Perspective: The Inner Sector of the Sarno Plain (Southern Apennines, Italy).

Author

Valente, Ettore, Allocca, Vincenzo, Riccardi, Umberto, Camanni, Giovanni, and Di Martire, Diego

Subjects

METROPOLITAN areas, HYDROGEOLOGY, ALLUVIAL plains, FAULT location (Engineering), LAND subsidence, PLAINS

Abstract

Defining the origin of ground deformation, which can be a very challenging task, may be approached through several investigative techniques. Ground deformation can originate in response to both natural (e.g., tectonics) and anthropic (e.g., groundwater pumping) contributions. These may either act simultaneously or be somewhat correlated in space and time. For example, the location of structurally controlled basins may be the locus of enhanced human-induced subsidence. In this paper, we investigate the natural and anthropic contributions to ground deformation in the urbanized area of the inner Sarno plain, in the Southern Apennines. We used a multidisciplinary approach based on the collection and analysis of a combination of geomorphological, stratigraphical, structural, hydrogeological, GPS, and DInSAR datasets. Geomorphological, stratigraphical, and structural data suggested the occurrence of a graben-like depocenter, the Sarno basin, bounded by faults with evidence of activity in the last 39 ka. Geodetic data indicated that the Sarno basin also experienced ground deformation (mostly subsidence) in the last 30 years, with a possible anthropogenic contribution due to groundwater pumping. Hydrogeological data suggested that a significant portion of the subsidence detected by geodetic data can be ascribed to groundwater pumping from the alluvial plain aquifer, rather than to a re-activation of faults in the last 30 years. Our interpretation suggested that a positive feedback exists between fault activity and the location of area affected by human-induced subsidence. In fact, fault activity caused the accumulation of poorly consolidated deposits within the Sarno basin, which enhanced groundwater-induced subsidence. The multidisciplinary approach used here was proven to be successful within the study area and could therefore be an effective tool for investigating ground deformation in other urbanized areas worldwide. [ABSTRACT FROM AUTHOR]

Published

2021

27. The Influence of Pre‐existing Basement Faults on the Cenozoic Structure and Evolution of the Proximal Domain, Northern South China Sea Rifted Margin.

Author

Ye, Qing, Mei, Lianfu, Shi, Hesheng, Du, Jiayuan, Deng, Peng, Shu, Yu, and Camanni, Giovanni

Abstract

In this paper, we investigate the structure of the Cenozoic rift basin in the proximal domain of the northern South China Sea (SCS) margin, with an emphasis on the influence exerted by pre‐existing basement faults on rift development. Results of our work indicate that the overall rift architecture of the proximal domain of the northern SCS margin is associated with extensional faults arranged in two main structural trends, WNW‐ to EW‐trending and ENE‐trending. Structural evidence presented in this paper suggests that extensional faults of the two main structural trends mainly reactivated two pre‐existing basement fault systems mapped in previous works, a WNW‐ to EW‐striking thrust fault system (PFS1) and an ENE‐striking thrust fault system (PFS2). During the first rifting phase, both pre‐existing fault systems were reactivated; however, strains and depocenters were mainly localized on the ENE‐striking normal fault system that reactivated the PFS2. On the contrary, in the second rifting phase, extension was mainly accommodated by WNW‐ to EW‐striking normal faults that reactivated the PFS1, while most of the earlier ENE‐striking normal faults became inactive or less active. These different degrees of reactivation of the two pre‐existing fault systems during the two rifting phases suggest a clockwise rotation of the regional extension direction from NNW‐SSE in the Syn‐rift stage 1 to N‐S in the Syn‐rift stage 2. This study implies that apart from Cenozoic tectonic processes, pre‐existing structures have also played a key role during rifting evolution across the SCS margin. Key Points: Two main structural trends in the proximal domain of the northern SCS rifted marginThe rift structure and evolution was significantly influenced by reactivation of two pre‐existing basement fault systemsChange of the regional extension direction from Syn‐rift 1 to Syn‐rift 2 indicated by reactivation pattern of pre‐existing fault systems [ABSTRACT FROM AUTHOR]

Published

2020

28. From competition to collaboration.

Author

Camanni, Giovanni

Subjects

*POSTDOCTORAL researchers, *COMPETITION (Psychology), *PSYCHOLOGICAL burnout

Abstract

This article presents a personal narrative by the author on his disillusionment regarding his work as a postdoctoral fellow, citing burnout, competition, and pressure.

Published

2019

29. Rift inheritance controls the switch from thin- to thick-skinned thrusting and basal décollement re-localization at the subduction-to-collision transition.

Author

Tavani, Stefano, Granado, Pablo, Corradetti, Amerigo, Camanni, Giovanni, Vignaroli, Gianluca, Manatschal, Gianreto, Mazzoli, Stefano, Muñoz, Josep A., and Parente, Mariano

Subjects

*RIFTS (Geology), *THRUST, *INHERITANCE & succession, *THRUST faults (Geology), *OROGENIC belts, *SUBDUCTION

Abstract

In accretionary convergent margins, the subduction interface is formed by a lower plate décollement above which sediments are scraped off and incorporated into the accretionary wedge. During subduction, the basal décollement is typically located within or at the base of the sedimentary pile. However, the transition to collision implies the accretion of the lower plate continental crust and deformation of its inherited rifted margin architecture. During this stage, the basal décollement may remain confined to shallow structural levels as during subduction or re-localize into the lower plate middle-lower crust. Modes and timing of such re-localization are still poorly understood. We present cases from the Zagros, Apennines, Oman, and Taiwan belts, all of which involve a former rifted margin and point to a marked influence of inherited rift-related structures on the décollement re-localization. A deep décollement level occurs in the outer sectors of all of these belts, i.e., in the zone involving the proximal domain of pre-orogenic rift systems. Older--and shallower--décollement levels are preserved in the upper and inner zones of the tectonic pile, which include the base of the sedimentary cover of the distal portions of the former rifted margins. We propose that thinning of the ductile middle crust in the necking domains during rifting, and its complete removal in the hyperextended domains, hampered the development of deep-seated décollements during the inception of shortening. Progressive orogenic involvement of the proximal rift domains, where the ductile middle crust was preserved upon rifting, favors its reactivation as a décollement in the frontal portion of the thrust system. Such décollement eventually links to the main subduction interface, favoring underplating and the upward motion of internal metamorphic units, leading to their final emplacement onto the previously developed tectonic stack. [ABSTRACT FROM AUTHOR]

Published

2021

30. Rift inheritance controls the switch from thin- to thick-skinned thrusting and basal décollement re-localization at the subduction-to-collision transition

Author

Pablo Granado, Gianreto Manatschal, Amerigo Corradetti, Stefano Tavani, Gianluca Vignaroli, Mariano Parente, Josep Anton Muñoz, Stefano Mazzoli, Giovanni Camanni, Institut Terre Environnement Strasbourg (ITES), École Nationale du Génie de l'Eau et de l'Environnement de Strasbourg (ENGEES)-Université de Strasbourg (UNISTRA)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Tavani, Stefano, Granado, Pablo, Corradetti, Amerigo, Camanni, Giovanni, Vignaroli, Gianluca, Manatschal, Gianreto, Mazzoli, Stefano, Muñoz, Josep A., and Parente, Mariano

Subjects

Décollement, Rift, passive margins, inheritance, 010504 meteorology & atmospheric sciences, Subduction, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], Geology, rift inheritance, accretionary margin, Apennines, Zagros, 010502 geochemistry & geophysics, Collision, 01 natural sciences, passive margin, Inheritance (object-oriented programming), Paleontology, Basal (phylogenetics), 0105 earth and related environmental sciences

Abstract

In accretionary convergent margins, the subduction interface is formed by a lower plate décollement above which sediments are scraped off and incorporated into the accretionary wedge. During subduction, the basal décollement is typically located within or at the base of the sedimentary pile. However, the transition to collision implies the accretion of the lower plate continental crust and deformation of its inherited rifted margin architecture. During this stage, the basal décollement may remain confined to shallow structural levels as during subduction or re-localize into the lower plate middle-lower crust. Modes and timing of such re-localization are still poorly understood. We present cases from the Zagros, Apennines, Oman, and Taiwan belts, all of which involve a former rifted margin and point to a marked influence of inherited rift-related structures on the décollement re-localization. A deep décollement level occurs in the outer sectors of all of these belts, i.e., in the zone involving the proximal domain of pre-orogenic rift systems. Older—and shallower—décollement levels are preserved in the upper and inner zones of the tectonic pile, which include the base of the sedimentary cover of the distal portions of the former rifted margins. We propose that thinning of the ductile middle crust in the necking domains during rifting, and its complete removal in the hyperextended domains, hampered the development of deep-seated décollements during the inception of shortening. Progressive orogenic involvement of the proximal rift domains, where the ductile middle crust was preserved upon rifting, favors its reactivation as a décollement in the frontal portion of the thrust system. Such décollement eventually links to the main subduction interface, favoring underplating and the upward motion of internal metamorphic units, leading to their final emplacement onto the previously developed tectonic stack.

Published

2021

31. Fracture density variations within a reservoir-scale normal fault zone: A case study from shallow-water carbonates of southern Italy

Author

Mariano Parente, Alessandro Iannace, Giovanni Camanni, Valeria Ferrandino, Stefano Tavani, Amerigo Corradetti, Stefano Mazzoli, Francesco Vinci, Camanni, G., Vinci, F., Tavani, S., Ferrandino, V., Mazzoli, S., Corradetti, A., Parente, M., Iannace, A., Camanni, Giovanni, Vinci, Francesco, Tavani, Stefano, Ferrandino, Valeria, Mazzoli, Stefano, Corradetti, Amerigo, Parente, Mariano, and Iannace, Alessandro

Subjects

geography, geography.geographical_feature_category, Outcrop, Geology, Slip (materials science), Fault (geology), Displacement (vector), Waves and shallow water, Photogrammetry, Fluid flow, Fault structure, 3D virtual outcrop model, Fracture density, Cliff, Fracture (geology), Petrology

Abstract

Fault zones can often display a complex internal structure associated with antithetic faults, branch and tip points, bed rotations, bed-parallel slip surfaces, and subordinate synthetic faults. We explore how these structural complexities may affect the development of fault-related fractures as displacement accumulates. We analysed in detail an incipient fault zone within well-bedded, shallow-water carbonates of the southern Apennines thrust belt (Italy). The fault zone crops out with quasi-complete exposure at a reservoir scale on an inaccessible sub-vertical cliff face, and fault and fracture mapping were carried out on a 3D virtual outcrop model of the exposure built for this study using photogrammetry. Comparing the structure of the fault zone and the density of 9444 mapped fractures allowed us to unravel their spatial relationships. Our results show that the areas of denser fractures coincide with: (i) rock volumes bounded by antithetic faults developed within the fault zone, (ii) branch points between these antithetic faults and fault zone-bounding fault segments, (iii) fault zone-bounding fault segments associated with significant displacement gradients, and (iv) relay zones between subordinate synthetic faults. These findings may aid locating sub-seismic resolution volumes of dense fracturing and associated enhanced permeability within faulted reservoirs.

Published

2021