170 resultados para petrologia sedimentaria
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El proceso de aprendizaje de las Ciencias de la Tierra, en particular en las disciplinas de la sedimentología y petrología sedimentaria, requiere de la realización de actividades prácticas, tanto en el campo como en el laboratorio. En este contexto examinar mediante lupa binocular distintos tipos de arena supone, además de un placer estético, un buen punto de partida para introducir al alumnado en la interpretación de ambientes sedimentarios. En este trabajo se propone un taller de iniciación a la reconstrucción de ambientes sedimentarios mediante el análisis de sedimentos detríticos (principalmente arenas). Se presenta una guía de procedimientos en laboratorio que incluye el análisis de los siguientes parámetros: tamaño, composición y forma de los granos, selección y color. Para vertebrar la propuesta didáctica se examinan ejemplos “tipo” de sedimentos detríticos representativos de ambientes de depósito tanto fluviales como marinos y de transición (playa), todos ellos incluidos en diferentes puntos de la geografía de la provincia de Alicante (España).
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Editors: v.1-6, G. Linck; v.7-10, A. Johnsen and others.
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The Firenzuola turbidite system formed during a paroxysmal phase of thrust propagation, involving the upper Serravallian deposits of the Marnoso-arenacea Formation (MAF). During this phase the coeval growth of two major tectonic structures, the M. Castellaccio thrust and the Verghereto high, played a key role, causing a closure of the inner basin and a coeval shift of the depocentre to the outer basin. This work focuses on this phase of fragmentation of the MAF basin; it is based on a new detailed high-resolution stratigraphic framework, which was used to determine the timing of growth of the involved structures and their direct influence on sediment dispersal and on the lateral and vertical turbidite facies distribution. The Firenzuola turbidite system stratigraphy is characterized by the occurrence of mass-transport complexes (MTCs) and thick sandstone accumulation in the depocentral area, which passes to finer drape over the structural highs; the differentiation between these two zones increases over time and ends with the deposition of marly units over the structural highs and the emplacement of the Visignano MTC. According to the stratigraphic pattern and turbidite facies characteristics, the Firenzuola System has been split into two phases, namely Firenzuola I and Firenzuola II: the former is quite similar to the underlying deposits, while the latter shows the main fragmentation phase, testifying the progressive isolation of the inner basin and a coeval shift of the depocentre to the outer basin. The final stratigraphic and sedimentological dataset has been used to create a quantitative high-resolution 3D facies distribution using the Petrel software platform. This model allows a detailed analysis of lateral and vertical facies variations that can be exported to several reservoirs settings in hydrocarbon exploration and exploitation areas, since facies distributions and geometries of the reservoir bodies of many sub-surface turbidite basins show a significant relationship to the syndepositional structural activity, but are beyond seismic resolution.
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The Cervarola Sandstones Formation (CSF), Aquitanian-Burdigalian in age, was deposited in an elongate, NW-stretched foredeep basin formed in front of the growing Northern Apennines orogenic wedge. The stratigraphic succession of the CSF, in the same way of other Apennine foredeep deposits, records the progressive closure of the basin due to the propagation of thrust fronts toward north-east, i.e. toward the outer and shallower foreland ramp. This process produce a complex foredeep characterized by synsedimentary structural highs and depocenters that can strongly influence the lateral and vertical turbidite facies distribution. Of consequence the main aim of this work is to describe and discuss this influence on the basis of a new high-resolution stratigraphic framework performed by measuring ten stratigraphic logs, for a total thickness of about 2000m, between the Secchia and Scoltenna Valleys (30km apart). In particular, the relationship between the turbidite sedimentation and the ongoing tectonic activity during the foredeep evolution has been describe through various stratigraphic cross sections oriented parallel and perpendicular to the main tectonic structures. On the basis of the high resolution physical stratigraphy of the studied succession, we propose a facies tract and an evolutionary model for the Cervarola Sandstones in the studied area. Thanks to these results and the analogies with others foredeep deposits of the northern Apennines, such as the Marnoso-arenacea Formation, the Cervarola basin has been interpreted as a highly confined foredeep controlled by an intense synsedimentary tectonic activity. The most important evidences supporting this hypothesis are: 1) the upward increase, in the studied stratigraphic succession (about 1000m thick), of sandstone/mudstone ratio, grain sizes and Ophiomorpha-type trace fossils testifying the high degree of flow deceleration related to the progressive closure and uplift of the foredeep. 2) the occurrence in the upper part of the stratigraphic succession of coarse-grained massive sandstones overlain by tractive structures such as megaripples and traction carpets passing downcurrent into fine-grained laminated contained-reflected beds. This facies tract is interpreted as related to deceleration and decoupling of bipartite flows with the deposition of the basal dense flows and bypass of the upper turbulent flows. 3) the widespread occurrence of contained reflected beds related to morphological obstacles created by tectonic structures parallel and perpendicular to the basin axis (see for example the Pievepelago line). 4) occurrence of intra-formational slumps, constituted by highly deformed portion of fine-grained succession, indicating a syn-sedimentary tectonic activity of the tectonic structures able to destabilize the margins of the basin. These types of deposits increase towards the upper part of the stratigraphic succession (see points 1 and 2) 5) the impressive lateral facies changes between intrabasinal topographic highs characterized by fine-grained and thin sandstone beds and marlstones and depocenters characterized by thick to very thick coarse-grained massive sandstones. 6) the common occurrence of amalgamation surfaces, flow impact structures and mud-draped scours related to sudden deceleration of the turbidite flows induced by the structurally-controlled confinement and morphological irregularities. In conclusion, the CSF has many analogies with the facies associations occurring in other tectonically-controlled foredeeps such as those of Marnoso-arenacea Formation (northern Italy) and Annot Sandstones (southern France) showing how thrust fronts and transversal structures moving towards the foreland, were able to produce a segmented foredeep that can strongly influence the turbidity current deposition.
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Los yacimientos de fósiles de vertebrados miocenos de Somosaguas y Húmera, objeto de estudio de esta Tesis Doctoral, están situadas en la cuenca cenozoica de Madrid. Esta cuenca presenta en superficie amplias extensiones de materiales sedimentarios neógenos, principalmente de edad miocena, que en su margen oeste son de una gran homogeneidad, siendo compleja su subdivisión y correlación con otras zonas de la cuenca mejor caracterizadas. Además, a pesar de guardar similitudes con otras áreas de la cuenca, de edades similares, al tener áreas fuente muy diversas (granitoides y gneisses al Oeste y Sur, rocas metamórficas de bajo grado al Norte y sedimentarias al Este) presenta particularidades diferenciales respecto a las demás zonas. Los yacimientos paleontológicos que se han encontrado en el área urbana de Madrid y en sus alrededores proporcionan una información muy valiosa, no solo en cuanto a la datación y la bioestratigrafía sino también en relación con las condiciones paleoambientales y paleoclimáticas. El interés de estos dos yacimientos es múltiple: (1) son los primeros encontrados en este área de Madrid y están entre los más occidentales de esta cuenca sedimentaria; (2) albergan una gran abundancia de restos fósiles; (3) son relativamente escasos los yacimientos formados en abanicos aluviales; (4) coinciden yacimientos con restos de macro y micromamíferos, posibilitando una buena caracterización del conjunto de la comunidad de mamíferos; (5) son de los pocos yacimientos de mamíferos de edad 14 m.a., coincidentes con el restablecimiento de la capa de hielo de la Antártida y un periodo de enfriamiento global; (6) presentan diversas modalidades de conservación de los fósiles en ambientes de sedimentación peculiares, y (7) son de muy fácil acceso y tienen una gran extensión. Además, por sus características el yacimiento de Somosaguas permite la iniciación de estudiantes de Geología y Biología en el estudio del Patrimonio paleontológico y geológico. El proyecto que lo gestiona (Proyecto Somosaguas de Paleontología) lleva aparejado una importante labor de divulgación e innovación educativa que se materializa principalmente en el Equipo de Introducción a la Investigación GeoPaleoBiológico de Somosaguas (EIIGPBS). A pesar de su cercanía estos dos yacimientos presentan algunas diferencias sedimentológicas, petrológicas, mineralógicas y tafonómicas que deben ser estudiadas para un mejor entendimiento de la geología y paleontología de la zona...
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Fossil associations from the middle and upper Eocene (Bartonian and Priabonian) sedimentary succession of the Pamplona Basin are described. This succession was accumulated in the western part of the South Pyrenean peripheral foreland basin and extends from deep-marine turbiditic (Ezkaba Sandstone Formation) to deltaic (Pamplona Marl, Ardanatz Sandstone and Ilundain Marl formations) and marginal marine deposits (Gendulain Formation). The micropalaeontological content is high. It is dominated by foraminifera, and common ostracods and other microfossils are also present. The fossil ichnoasssemblages include at least 23 ichnogenera and 28 ichnospecies indicative of Nereites, Cruziana, Glossifungites and ?Scoyenia-Mermia ichnofacies. Body macrofossils of 78 taxa corresponding to macroforaminifera, sponges, corals, bryozoans, brachiopods, annelids, molluscs, arthropods, echinoderms and vertebrates have been identified. Both the number of ichnotaxa and of species (e. g. bryozoans, molluscs and condrichthyans) may be considerably higher. Body fossil assemblages are comparable to those from the Eocene of the Nord Pyrenean area (Basque Coast), and also to those from the Eocene of the west-central and eastern part of South Pyrenean area (Aragon and Catalonia). At the European scale, the molluscs assemblages seem endemic from the Pyrenean area, although several Tethyan (Italy and Alps) and Northern elements (Paris basin and Normandy) have been recorded. Palaeontological data of studied sedimentary units fit well with the shallowing process that throughout the middle and late Eocene occurs in the area, according to the sedimentological and stratigraphical data.
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In this paper we analyze the set of Bronze Age bone tools recovered at the archaeological site of El Portalón of Cueva Mayor in the Sierra de Atapuerca (Burgos). The Bronze Age cultural period is the best represented in the cavity and its study has forced us to unify the different excavation and stratigraphical criteria undertaken from the earliest archaeological excavations developed by J.M. Apellániz during the 70s until the excavations of the current research team (EIA) since 2000. We propose here for the first time a relationship between the initial system of “beds” used by Apellániz and our recent sedimentary sequence that recognizes eleven stratigraphic levels radiometrically dated from the late Upper Pleistocene to the Middle Age. Within the bone industry assemblage we recognize a large variety of utensils and ornamental elements, with native and allochthonous features, that make evident a regional as well as long distance relationships of these populations of the interior of the Iberian Peninsula during the recent Prehistory.
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Durante el siglo XIII se produjo una sucesión de revueltas que supuso la desaparición del Imperio almohade y su sustitución por poderes regionales en al-Andalus, el Magreb y el Magreb al-Aqsà. La historiografía ha presentado el surgimiento y pugna entre estos poderes como un fenómeno social, político e, incluso, cultural y religioso, con el que se ha podido explicar su aniquilación o marginalización. Este trabajo pretende contextualizar los hechos desde una perspectiva medioambiental, de forma que la desintegración del califato almohade, el surgimiento de aquellos poderes y la progresión de los reinos cristianos en la península ibérica puedan entenderse desde una visión global de cambio climático y una posible crisis agrícola.
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Il contenuto di questo volume non vuole rappresentare un testo didattico per lo studio in generale della vulcanologia in quanto in esso si tratta unicamente quell’a-spetto della disciplina che riguarda il vulcanismo esplosivo. In tal senso l’autore ritiene che questo testo possa essere utile per gli studenti di Scienze Geologiche che, vivendo nelle aree vulcaniche italiane di età quaternaria ed anche attive, possano, da laureati, svolgere attività professionali mirate alla individuazione e definizione di Pericolosità, Vulnerabilità e Rischio Vulcanico. Trattare gli argomenti che seguono non è stato facile e forse si poteva, in alcuni casi, renderli più semplici, ma talvolta la semplicità non sempre è sinonimo di precisione; inoltre, per descrivere certi aspetti non quantitativi si è costretti ad utilizzare un linguaggio quanto più possibile “ad hoc”. L’autore ha svolto la propria attività di ricerca in aree vulcaniche, sia in Italia che all’estero. Le ricerche in Italia sono state da sempre concentrate nelle aree di vulcanismo attivo in cui l’attività del vulcanologo è finalizzata fondamentalmente alla definizione della Pericolosità Vulcanica supporto indispensabile per la definizione dell’aree a Rischio Vulcanico, intendendo per Rischio il prodotto della Pericolosità per il Danno in termini, questo, di numero di vite umane ovvero di valore monetario dei beni a rischio nell’area vulcanica attiva. Le ricerche svolte dall’autore in Africa Orientale (Etiopia e Somalia) e nello Yemen hanno contribuito ad assimilare i concetti di vulcanologia regionale, rappresentata dall’ampia diffusione del vulcanismo di plateau, variabile per spessore dai 1500 ai 3000 metri, fra i quali si inseriscono, nella depressione dell’Afar, catene vulcaniche inquadrabili, dal punto di vista geodinamico, come “oceaniche” alcune delle quali attive e che si sviluppano per decine/centinaia di chilometri. Nelle aree vulcaniche italiane le difficoltà che sorgono durante il rilevamento risiedono nella scarsa continuità di affioramenti, talvolta incompleti per la descrizione delle variazioni di facies piroclastiche, non disgiunta dalla fitta vegetazione ovvero ur banizzazione specialmente nelle aree di vulcanismo attivo. Il rilevamento vulcanologico richiede competenze e l’adozione di scale adatte a poter cartografare le variazioni di facies piroclastiche che, a differenza dalle assise sedimentarie, in un’area vulcanica possono essere diffuse arealmente soltanto per alcune centinaia di metri. I metodi di studio delle rocce piroclastiche sono del tutto simili a quelli che si usano per le rocce clastiche, cioè dall’analisi delle strutture e delle tessiture alla litologica fino a quella meccanica; su questi clasti inoltre le determinazioni della densità, della mineralogia e della geochimica (Elementi in tracce e Terre Rare), ottenute sulla frazione vetrosa, rappresentano parametri talvolta identificativi di un’area vulcanica sorgente. Non esistono testi nei quali venga descritto come si debba operare nelle aree vulcaniche per le quali l’unica certezza unificante è rappresentata dall’evidenza che, nelle sequenze stratigrafiche, il termine al top rappresenta quello più relativamente recente mentre quello alla base indica il termine relativo più vecchio. Quanto viene riportato in questo testo nasce dall’esperienza che è stata acquisita nel tempo attraverso una costante azione di rilevamento che rappresenta l’uni- ca sorgente di informazione che un vulcanologo deve ricavare attraverso un attento esame dei depositi vulcanici (dalla litologia alla mineralogia, alla tessitura, etc.) la cui distribuzione, talvolta, può assumere un carattere interegionale in Italia nell’ambito dell’Olocene. Soltanto l’esperienza acquisita con il rilevamento produce, in un’area di vulcanismo attivo, risultati positivi per la definizione della Pericolosità, sapendo però che le aree vulcaniche italiane presentano caratteristiche ampiamente differenti e di conseguenza il modo di operare non può essere sempre lo stesso. Un esempio? Immaginate di eseguire un rilevamento vulcanico prima al Somma-Vesuvio e poi nei Campi Flegrei: sono mondi completamente differenti. L’autore desidera ribadire che questo testo si basa sulla esperienza acquisita sia come geologo sia come docente di Vulcanologia; pertanto il libro potrà forse risultare più o meno bilanciato, in forza dell’argomento trattato, in quanto durante l’attività di ricerca l’autore, come tutti, ha affrontato alcuni argomenti più di altri. Questo approccio può essere considerato valido per chiunque voglia scrivere un libro in maniera autonoma e originale, non limitandosi, come molte volte avviene, a tradurre in italiano un libro su tematiche analoghe diffuso, ad esempio, nel mondo anglosassone.Diversamente, si sarebbe potuto concepire un libro come un collage di capitoli scritti da vari autori, che magari avevano esperienza più specifica nei singoli argomenti, ma in tal senso si sarebbe snaturato lo spirito con cui si è impostato il progetto. L’autore, infine, ha fatto ricorso al contributo di altri autorevoli colleghi solo per temi importantissimi, ma in qualche modo complementari rispetto al corpus costitutivo del Vulcanismo Esplosivo.
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This book presents research in the field of Geophysics, particularly referring to principles, applications and emerging technologies. Table of Contents: Preface pp. i-xxi Environmental Geophysics: Techniques, advantages and limitations (Pantelis Soupios and Eleni Kokinou, Department of Environmental and Natural Resources Engineering, Technological Educational Institute of Crete, Dynamics of the Ocean Floor, Helmholtz Centre for Ocean Research Kiel, Geomar)pp i-xxi Application of Innovative Geophysical Techniques in Coastal Areas (V. Di Fiore, M. Punzo, D. Tarallo, and G. Cavuoto, Institute for Marine Coastal Environment, National Research Council, Naples)pp. i-xxi Marine Geophysics of the Naples Bay (Southern Tyrrhenian sea, Italy): Principles, Applications and Emerging Technologies (Gemma Aiello and Ennio Marsella, Institute for Marine Coastal Environment, National Research Council, Naples)pp. i-xxi Oceanic Oscillation Phenomena: Relation to Synchronization and Stochastic Resonance (Shinya Shimokawa and Tomonori Matsuura, National Research Institute for Earth Science and Disaster Prevention, Univ. of Toyama)pp. i-xxi Assessment of ocean variability in the Sicily Channel from a numerical three-dimensional model using EOFs decomposition (R. Sorgente, A. Olita, A.F. Drago, A. Ribotti, L. Fazioli, and C. Tedesco, Institute for Marine Coastal Environment, National Research Council, Oristano)pp. i-xxi Monitoring Test of Crack Opening in Volcanic Tuff (Coroglio Cliff. Italy) Using Distributed Optical Fiber Sensor (A. Minardo, A. Coscetta, M. Caccavale, G. Esposito, F. Matano, M. Sacchi, R. Somma, G. Zeni, and L. Zeni, Department of Industrial and Information Eng., Second University of Naples Aversa, Institute for Marine Coastal Environment, National Research Council Naples, National Institute for Geophysics and Volcanology, Osservatorio Vesuviano Naples, Institute for Electromagnetic Sensing of the Environment, National Research Council Naples)pp. i-xxi
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New morpho-bathymetric and tectono-stratigraphic data on Naples and Salerno Gulfs, derived from bathymetric and seismic data analysis and integrated geologic interpretation are here presented. The CUBE(Combined Uncertainty Bathymetric Estimator) method has been applied to complex morphologies, such as the Capri continental slope and the related geological structures occurring in the Salerno Gulf.The bathymetric data analysis has been carried out for marine geological maps of the whole Campania continental margin at scales ranging from 1:25.000 to 1:10.000, including focused examples in Naples and Salerno Gulfs, Naples harbour, Capri and Ischia Islands and Salerno Valley. Seismic data analysis has allowed for the correlation of main morpho-structural lineaments recognized at a regional scale through multichannel profiles with morphological features cropping out at the sea bottom, evident from bathymetry.Main fault systems in the area have been represented on a tectonic sketch map, including the master fault located northwards to the Salerno Valley half graben. Some normal faults parallel to the master fault have been interpreted from the slope map derived from bathymetric data. A complex system of antithetic faults bound two morpho-structural highs located 20km to the south of the Capri Island. Some hints of compressional reactivation of normal faults in an extensional setting involving the whole Campania continental margin have been shown from seismic interpretation.
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The interactions between Late Quaternary volcanic and sedimentary processes in the Naples Bay, Southern Tyrrhenian sea, are here discussed through the results of the marine geological survey at the scale 1:25.000. The example of the geological map n. 465 “Isola di Procida”, herein presented, has put in evidence the stratigraphy of marine Quaternary deposits and related volcanic seismic units. The volcanic deposits cropping out in the Procida island have been explained as the result of eruptions of local eruptive centres. The geological survey carried out onshore indicates the occurrence of several pyroclastic units linked to the eruptive activity of the Ischian and Phlegrean volcanic complexes, interstratified with the products erupted by local volcanic centres. The occurrence in the pyroclastic sequences of Ischia and Procida islands of several marker horizons and their stratigraphic correlations have allowed to reconstruct the volcanological evolution of the two islands and the interactions with sedimentary processes at the scale of the whole Tyrrhenian margin. Four geological maps at the scale 1:25.000 covering the whole Naples Bay have been reconstructed based on the interpretation of marine geological and geophysical data. The stratigraphic relationships between the seismic units and the eruptive deposits have testified the activity of several monogenetic volcanic centers, whose products are interstratified with marine and continental deposits of the Late Quaternary depositional sequence.
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The stratigraphic architecture of deep sea depositional systems has been discussed in detail. Some examples in Ischia and Stromboli volcanic islands (Southern Tyrrhenian sea, Italy) are here shown and discussed. The submarine slope and base of slope depositional systems represent a major component of marine and lacustrine basin fills, constituting primary targets for hydrocarbon exploration and development. The slope systems are characterized by seven seismic facies building blocks, including the turbiditic channel fills, the turbidite lobes, the sheet turbidites, the slide, slump and debris flow sheets, lobes and tongues, the fine-grained turbidite fills and sheets, the contourite drifts and finally, the hemipelagic drapes and fills. Sparker profiles offshore Ischia are presented. New seismo-stratigraphic evidence on buried volcanic structures and overlying Quaternary deposits of the eastern offshore of the Ischia Island are here discussed to highlight the implications on marine geophysics and volcanology. Regional seismic sections in the Ischia offshore across buried volcanic structures and debris avalanche and debris flow deposits are here presented and discussed. Deep sea depositional systems in the Ischia Island are well developed in correspondence to the Southern Ischia canyon system. The canyon system engraves a narrow continental shelf from Punta Imperatore to Punta San Pancrazio, being limited southwestwards from the relict volcanic edifice of the Ischia bank. While the eastern boundary of the canyon system is controlled by extensional tectonics, being limited from a NE-SW trending (counter-Apenninic) normal fault, its western boundary is controlled by volcanism, due to the growth of the Ischia volcanic bank. Submarine gravitational instabilities also acted in relationships to the canyon system, allowing for the individuation of large scale creeping at the sea bottom and hummocky deposits already interpreted as debris avalanche deposits. High resolution seismic data (Subbottom Chirp) coupled to high resolution Multibeam bathymetry collected in the frame of the Stromboli geophysical experiment aimed at recording seismic active data and tomography of the Stromboli Island are here presented. A new detailed swath bathymetry of Stromboli Island is here shown and discussed to reconstruct an up-to-date morpho-bathymetry and marine geology of the area, compared to volcanologic setting of the Aeolian volcanic complex. The Stromboli DEM gives information about the submerged structure of the volcano, particularly about the volcano-tectonic and gravitational processes involving the submarine flanks of the edifice. Several seismic units have been identified around the volcanic edifice and interpreted as volcanic acoustic basement pertaining to the volcano and overlying slide chaotic bodies emplaced during its complex volcano-tectonic evolution. They are related to the eruptive activity of Stromboli, mainly poliphasic and to regional geological processes involving the geology of the Aeolian Arc.
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Magnetic theory and application to a complex volcanic area located in Southern Italy are here discussed showing the example of the Gulf of Naples, located at Southern Italy Tyrrhenian margin. A magnetic anomaly map of the Gulf of Naples has been constructed aimed at highlighting new knowledge on geophysics and volcanology of this area of the Eastern Tyrrhenian margin, characterized by a complex geophysical setting, strongly depending on sea bottom topography. The theoretical aspects of marine magnetometry and multibeam bathymetry have been discussed. Magnetic data processing included the correction of the data for the diurnal variation, the correction of the data for the offset and the leveling of the data as a function of the correction at the cross-points of the navigation lines. Multibeam and single-beam bathymetric data processing has been considered. Magnetic anomaly fields in the Naples Bay have been discussed through a detailed geological interpretation and correlated with main morpho-structural features recognized through morphobathymetric interpretation. Details of magnetic anomalies have been selected, represented and correlated with significant seismic profiles, recorded on the same navigation lines of magnetometry. They include the continental shelf offshore the Somma-Vesuvius volcanic complex, the outer shelf of the Gulf of Pozzuoli offshore the Phlegrean Fields volcanic complex, the relict volcanic banks of Pentapalummo, Nisida and Miseno, the Gaia volcanic bank on the Naples slope, the western slope of the Dohrn canyon, the Magnaghi canyon’s head and the magnetic anomalies among the Ischia and Procida islands.
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283 p.
