Rapporti tra tettonica e clima durante l'esumazione nelle Alpi Centrali. Evidenze dalla termocronologia e dall'analisi strutturale lungo il traforo ferroviario del Sempione

Pignalosa, Antonio <1982>

06 April 2009

(U-Th)/He and fission-track analyses of apatite along deep-seated tunnels crossing high-relief mountain ranges offer the opportunity to investigate climate and tectonic forcing on the topographic evolution. In this study, the thermochronologic analysis of a large set of samples collected in the Simplon railway tunnel (western-central Alps; Italy and Switzerland) and along its surface trace, coupled with kinematic and structural analysis of major fault zones intersecting the tunnel, constrains the phenomena controlling the topographic and structural evolution, during the latest stage of exhumation of the Simplon Massif, and the timing in which they operated. The study area is located at the western margin of the Lepontine metamorphic dome where a complex nappe-stack pertaining to the Penninic and Ultrahelvetic domains experienced a fast exhumation from the latest Oligocene onward. The exhumation was mainly accommodated by a west-dipping low-angle detachment (the Simplon Fault Zone) which is located just 8 km to the west of the tunnel. However, along the section itself several faults related to two principal phases both with important dip-slip kinematics have been detected. Cooling rates derived from our thermocronological data vary from about 10 °C/Ma at about 10 Ma to about 35 °C/Ma in the last 5 Ma. Such increase in the cooling rate corresponds to the most important climatic change recorded in the northern hemisphere in the last 10 Ma, i.e. the shift to wetter conditions at the end of the Messinian salinity crisis and the inception of glacial cycles in the northern hemisphere. In addition, (U-Th)/He and fission-track age patterns lack of important correlation with the topography suggesting that the present-day relief morphology is the result of recent erosional dynamics. More in details, the (U-Th)/He tunnel ages show an impressive uniformity at 2 Ma, whereas cooling rates calculated at 1 Ma increase towards the two major valleys. This indicates a focusing of erosive processes in the valleys which led to the shaping of present-day topography. Structural analysis documents the presence of two phases of brittle deformation postdating the metamorphic phases in the area. The first one is directly related to the last phase of activity along the Simplon Fault Zone and is characterized by extension towards SO and vertical shortening. The young one is characterized by extension towards NO and horizontal shortening in a along the NE-SO direction. Structures related to the first phase of brittle deformation generate important variations in the older ages' dataset, until 3 Ma, suggesting that tectonics controlled rocks exhumation up to that age. Structures related to the second phase generate some variations also in the younger age dataset, highlighting the activity of faults bordering the massif and suggesting a continuous activity also after 2 Ma. However, most of (U-Th)/He tunnel ages, varying slightly around 2 Ma, document that the Simplon area has experienced primarily erosional exhumation in this time span. In conclusion, all our data suggest that in the central Italian Alps the climatic signal gradually overrode the tectonic effects after about 5 Ma, as a consequence of the climatic instability started at end of Messinian salinity crisis and improved by the onset of glaciations in the northern hemisphere.

GEO/03 Geologia strutturale

Characterization of fold-related fractures in the carbonate rocks of the Cingoli anticline, northern Apennines, Italy

Petracchini, Lorenzo <1979>

19 April 2013

Thrust fault-related folds in carbonate rocks are characterized by deformation accommodated by different structures, such as joints, faults, pressure solution seams, and deformation bands. Defining the development of fracture systems related to the folding process is significant both for theoretical and practical purposes. Fracture systems are useful constrains in order to understand the kinematical evolution of the fold. Furthermore, understanding the relationships between folding and fracturing provides a noteworthy contribution for reconstructing the geodynamic and the structural evolution of the studied area. Moreover, as fold-related fractures influence fluid flow through rocks, fracture systems are relevant for energy production (geothermal studies, methane and CO2 , storage and hydrocarbon exploration), environmental and social issues (pollutant distribution, aquifer characterization). The PhD project shows results of a study carried out in a multilayer carbonate anticline characterized by different mechanical properties. The aim of this study is to understand the factors which influence the fracture formation and to define their temporal sequence during the folding process. The studied are is located in the Cingoli anticline (Northern Apennines), which is characterized by a pelagic multilayer characterized by sequences with different mechanical stratigraphies. A multi-scale analysis has been made in several outcrops located in different structural positions. This project shows that the conceptual sketches proposed in literature and the strain distribution models outline well the geometrical orientation of most of the set of fractures observed in the Cingoli anticline. On the other hand, the present work suggests the relevance of the mechanical stratigraphy in particular controlling the type of fractures formed (e.g. pressure solution seams, joints or shear fractures) and their subsequent evolution. Through a multi-scale analysis, and on the basis of the temporal relationship between fracture sets and their orientation respect layering, I also suggest a conceptual model for fracture systems formation. / Le anticlinali carbonatiche presentano un’intensa fratturazione indotta dalla deformazione durante il piegamento. Caratterizzare e comprendere lo sviluppo dei sistemi di fratture collegati al processo plicativo risulta essere di notevole interesse sia da un punto di vista scientifico che applicativo. I sistemi di fratture forniscono un contributo fondamentale per la comprensione dell’evoluzione cinematica della pieghe, inoltre, la comprensione delle relazioni tra sistemi di fratture e pieghe può contribuire a definire l'evoluzione strutturale dell'area di studio. Da un punto di vista applicativo è ormai noto come i sistemi di fratture incidono enormemente sulla circolazione dei fluidi. Di conseguenza la loro definizione trova un'applicazione importante nel settore energetico (flussi geotermici, stoccaggio gas e CO2, esplorazione petrolifera), ambientale (dispersione di inquinanti nel sottosuolo), e sociale (caratterizzazione degli acquiferi ecc.). La tesi di Dottorato presenta uno studio sull’analisi e la caratterizzazione di sistemi di fratture in un’anticlinale carbonatica caratterizzata da un multistrato con diverse caratteristiche meccaniche. Il progetto di Dottorato si pone l’obiettivo di comprendere i fattori che maggiormente influenzano le proprietà dei sistemi di fratture e di definire la loro evoluzione nel tempo. A tal fine è stata analizzata l’anticlinale di Cingoli (Appennino settentrionale) che espone una serie di interessanti affioramenti in calcari pelagici. Attraverso analisi a diverse scale di osservazione sono stati quindi caratterizzati i sistemi di fratture in affioramenti posizionati lungo tutta l’anticlinale e in diverse posizioni strutturali. Nel lavoro è stato osservato e discusso come la posizione strutturale e soprattutto la stratigrafia meccanica influiscono sulla formazione dei sistemi di fratture. In particolare è stato osservato come i modelli proposti in letteratura sintetizzano e schematizzano bene l’assetto geometrico di alcune fratture osservate a Cingoli. In questo lavoro, però, si è evidenziato come la stratigrafia meccanica ha un ruolo decisivo soprattutto per quanto riguarda la tipologia meccanica di fratture.

GEO/03 Geologia strutturale

Transform Tectonics and Non-Volcanic Oceanic Islands / Dinamica trasforme e formazione di isole oceaniche non-vulcaniche

Palmiotto, Camilla <1985>

07 April 2014

Oceanic islands can be divided, according to their origin, in volcanic and tectonic. Volcanic islands are due to excess volcanism. Tectonic islands are mainly formed due to vertical tectonic motions of blocks of oceanic lithosphere along transverse ridges flanking transform faults at slow and ultraslow mid-ocean ridges. Vertical tectonic motions are due to a reorganization of the geometry of the transform plate boundary, with the transition from a transcurrent tectonics to a transtensive and/or transpressive tectonics, with the formation of the transverse ridges. Tectonic islands can be located also at the ridge–transform intersection: in this case the uplift is due by the movement of the long-lived detachment faults located along the flanks of the mid-ocean ridges. The "Vema" paleoisland (equatorial Atlantic) is at the summit of the southern transverse ridge of the Vema transform. It is now 450 m bsl and it is capped by a carbonate platform 500 m-thick, dated by 87Sr/86Sr at 10 Ma. Three tectonic paleoislands are on the summit of the transverse ridge flanking the Romanche megatrasform (equatorial Atlantic). They are now about 1,000 m bsl and they are formed by 300 m-thick carbonate platforms dated by 87Sr/86Sr, between 11 and 6 Ma. The tectonic paleoisland “Atlantis Bank" is located in the South-Western Indian Ridge, along the Atlantis II transform, and it is today 700 m bsl. The only modern example of oceanic tectonics island is the St. Paul Rocks (equatorial Atlantic), located along the St. Paul transform. This archipelago is the top of a peridotitic massif that it is now a left overstep undergoing transpression. Oceanic volcanic islands are characterized by rapid growth and subsequent thermal subsidence and drowning; in contrast, oceanic tectonic islands may have one or more stages of emersion related to vertical tectonic events along the large oceanic fracture zones.

GEO/03 Geologia strutturale

Evoluzione Morfotettonica delle Aree Alpine "Sempione" e "Brennero" attraverso Studi Termocronologici di bassa temperatura / Morphotectonical evolution of "Simplon" and "Brenner" Alpine regions through low temperature thermochronological studies

Di Fiore, Giorgio <1984>

13 April 2012

E’ mostrata l’analisi e la modellazione di dati termocronologici di bassa temperatura da due regioni Alpine: il Sempione ed il Brennero. Le faglie distensive presenti bordano settori crostali profondi appartenenti al dominio penninico: il duomo metamorfico Lepontino al Sempione e la finestra dei Tauri al Brennero. I dati utilizzati sono FT e (U-Th)/He su apatite. Per il Sempione i dati provengono dalla bibliografia; per il Brennero si è provveduto ad un nuovo campionamento, sia in superficie che in sotterraneo. Gli attuali lavori per la galleria di base del Brennero (BBT), hanno consentito, per la prima volta, di raccogliere dati di FT e (U-Th)/He in apatite in sottosuolo per la finestra dei Tauri occidentale. Le analisi sono state effettuate tramite un codice a elementi finiti, Pecube, risolvente l’equazione di diffusione del calore per una topografia evolvente nel tempo. Il codice è stato modificato per tener conto dei dati sotterranei. L’inversione dei dati è stata effettuata usando il Neighbourhood Algorithm (NA), per ottenere il più plausibile scenario di evoluzione morfotettonico. I risultati ottenuti per il Sempione mostrano: ipotetica evoluzione dello stile tettonico della faglia del Sempione da rolling hinge a low angle detachment a 6.5 Ma e la cessazione dell’attività a 3 Ma; costruzione del rilievo fino a 5.5 Ma, smantellamento da 5.5 Ma ad oggi, in coincidenza dei cambiamenti climatici Messiniani e relativi all’inizio delle maggiori glaciazioni; incremento dell’esumazione da 0–0.6 mm/anno a 0.6–1.2 mm/anno a 2.4 Ma nell’emisfero settentrionale. I risultati al Brennero mostrano: maggiore attività tettonica della faglia del Brennero (1.3 mm/anno), maggiore attività esumativa (1–2 mm/anno) prima dei 10 Ma; crollo dell’attività della faglia del Brennero fra 10 Ma e oggi (0.1 mm/anno) e dell’attività esumativa nello stesso periodo (0.1–0.3 mm/anno); nessun aumento del tasso esumativo o variazioni topografiche negli ultimi 5 Ma. / This work concerns the uplift and exhumation history of Simplon and Brenner Alpine regions by means of low-temperature thermochronological analysis (apatite FT and U-Th/He) and modeling. Simplon and Brenner normal faults border deep crustal sectors belonging to the Penninic domain: Lepontine dome core complex for Simplon; ophiolitic units and Penninic basement and covers units for Brenner. Data were collected from literature for the Simplon, whereas a surface and subsurface sampling was provided for the Brenner. In the latter case the realization of the Brenner tunnel (BBT) allowed, for the first time, to collect underground apatite FT and (U-Th)/He data for the western Tauern window. Modeling was made using: a finite elements code that computes the solution of the heat diffusion equation for a time varying topography, Pecube (whose code was modified during this thesis in order to take into account underground data; an inversion procedure by the Neighbourhood Algorithm (NA), with the aim to obtain the most plausible morphotectonic scenario. Results for the Simplon region show: an hypothetic change of the tectonic style of the Simplon fault from rolling hinge to low angle detachment at 6.5 Ma, and the cessation of its activity at 3 Ma; relief construction until 5.5 Ma followed by dismantle between 5.5 and 0 Ma, during the climatic changes of Messinian age and related to glacial cycles onset on the northern hemisphere; increment of exhumation activity (0–0.6 mm/yr to 0.6–1.2 mm/yr) when glaciations on the northern hemisphere began. Brenner results show: major fault (1.3 mm/yr) activity of the Brenner line as well as a major exhumation (1 - 2 mm/yr) before 10 Ma; fault activity (0.1 mm/yr) and exhumation (0.1–0.3 mm/yr) decrease between 10 and 0 Ma; no exhumation rate increase or evident topographic changes during the glacial cycles.

GEO/03 Geologia strutturale

Geological and Structural evolution of the Eurasia Africa plate boundary in the Gulf of Cadiz Central Eastern Atlantic Sea.

D’Oriano, Filippo <1980>

09 April 2010

Iberia Africa plate boundary, cross, roughly W-E, connecting the eastern Atlantic Ocean from Azores triple junction to the Continental margin of Morocco. Relative movement between the two plate change along the boundary, from transtensive near the Azores archipelago, through trascurrent movement in the middle at the Gloria Fracture Zone, to transpressive in the Gulf of Cadiz area. This study presents the results of geophysical and geological analysis on the plate boundary area offshore Gibraltar. The main topic is to clarify the geodynamic evolution of this area from Oligocene to Quaternary. Recent studies have shown that the new plate boundary is represented by a 600 km long set of aligned, dextral trascurrent faults (the SWIM lineaments) connecting the Gloria fault to the Riff orogene. The western termination of these lineaments crosscuts the Gibraltar accretionary prism and seems to reach the Moroccan continental shelf. In the past two years newly acquired bathymetric data collected in the Moroccan offshore permit to enlighten the present position of the eastern portion of the plate boundary, previously thought to be a diffuse plate boundary. The plate boundary evolution, from the onset of compression in the Oligocene to the Late Pliocene activation of trascurrent structures, is not yet well constrained. The review of available seismics lines, gravity and bathymetric data, together with the analysis of new acquired bathymetric and high resolution seismic data offshore Morocco, allows to understand how the deformation acted at lithospheric scale under the compressive regime. Lithospheric folding in the area is suggested, and a new conceptual model is proposed for the propagation of the deformation acting in the brittle crust during this process. Our results show that lithospheric folding, both in oceanic and thinned continental crust, produced large wavelength synclines bounded by short wavelength, top thrust, anticlines. Two of these anticlines are located in the Gulf of Cadiz, and are represented by the Gorringe Ridge and Coral Patch seamounts. Lithospheric folding probably interacted with the Monchique – Madeira hotspot during the 72 Ma to Recent, NNE – SSW transit. Plume related volcanism is for the first time described on top of the Coral Patch seamount, where nine volcanoes are found by means of bathymetric data. 40Ar-39Ar age of 31.4±1.98 Ma are measured from one rock sample of one of these volcanoes. Analysis on biogenic samples show how the Coral Patch act as a starved offshore seamount since the Chattian. We proposed that compression stress formed lithospheric scale structures playing as a reserved lane for the upwelling of mantle material during the hotspot transit. The interaction between lithospheric folding and the hotspot emplacement can be also responsible for the irregularly spacing, and anomalous alignments, of individual islands and seamounts belonging to the Monchique - Madeira hotspot.

GEO/03 Geologia strutturale

The role of the fluid phase in the chemico-mechanical evolution of a mid-crustal shear zone: an example from Alpine Corsica

Maggi, Matteo <1981>

06 May 2011

No description available.

GEO/07 Petrologia e petrografia

GEO/03 Geologia strutturale

GEO/10 Geofisica della terra solida

GEO/08 Geochimica e vulcanologia