Your search keyword '"Castellanos D"' showing total 5 results

1. Restoration of paleo-shorelines through lithospheric 3d modeling and backstripping analysis: The example of the po plain-northern adriatic region during late messinian sealevel drop

Author

CHIARA AMADORI, Toscani, G., Di Giulio, A., Garcia-Castellanos, D., Fantoni, R., Ghielmi, M., García-Castellanos, Daniel, and García-Castellanos, Daniel [0000-0001-8454-8572]

Subjects

Image reconstruction, Sea level, Drops, Fertilizers, Seismology

Abstract

We present a case history of 3D modeling and backstripping analysis of the paleo-topographic surface developed in the Po Plain–Northern Adriatic region during Latest Messinian sea-level drop occurred in the Mediterranean region, with special emphasis on the reconstruction of the paleocoastline position. The model results from the integration of 2D seismic interpretation, backstripping and numerical modeling at a lithospheric scale using TISC program (Garcia-Castellanos et al., 2002; 2003) considering both the loading of the Plio-Pleistocene sediments and the regional amount of sea-level drop reported in the literature (Ghielmi et al., 2013, Rossi et al., 2015). The best fit between facies distribution maps and the resulting modeled coastline has been reached imposing a sea level drop of only 850m. This value is quite different from the ca.1500m calculated for the Mediterranean basin, thus suggesting that the Po Plain-Adriatic basin was an isolated sub-basin from the eastern Mediterranean, protected from a complete desiccation by a sill located in the Southern Adriatic Sea. Thanks to this fruitful cooperation between industry and academia, it is now possible to describe the entire 3D basin geometry and the facies distribution during the Latest Messinian time, including the expected position of potential exploration targets provided by coarse-grained deltaic complexes presumably developed at the mouths of riverine systems during the Messinian Salinity Crisis and then sealed by Pliocene marine marls.

Published

2017

2. Messinian salinity crisis regulated by competing tectonics and erosion at the Gibraltar arc.

Author

Garcia-Castellanos, D. and Villaseñor, A.

Subjects

*SALINITY & the environment, *SEA level, *DATA modeling, *STRUCTURAL geology

Abstract

The Messinian salinity crisis (5.96 to 5.33 million years ago) was caused by reduced water inflow from the Atlantic Ocean to the Mediterranean Sea resulting in widespread salt precipitation and a decrease in Mediterranean sea level of about 1.5 kilometres due to evaporation. The reduced connectivity between the Atlantic and the Mediterranean at the time of the salinity crisis is thought to have resulted from tectonic uplift of the Gibraltar arc seaway and global sea-level changes, both of which control the inflow of water required to compensate for the hydrological deficit of the Mediterranean. However, the different timescales on which tectonic uplift and changes in sea level occur are difficult to reconcile with the long duration of the shallow connection between the Mediterranean and the Atlantic needed to explain the large amount of salt precipitated. Here we use numerical modelling to show that seaway erosion caused by the Atlantic inflow could sustain such a shallow connection between the Atlantic and the Mediterranean by counteracting tectonic uplift. The erosion and uplift rates required are consistent with previous mountain erosion studies, with the present altitude of marine sediments in the Gibraltar arc and with geodynamic models suggesting a lithospheric slab tear underneath the region. The moderate Mediterranean sea-level drawdown during the early stages of the Messinian salinity crisis can be explained by an uplift of a few millimetres per year counteracted by similar rates of erosion due to Atlantic inflow. Our findings suggest that the competition between uplift and erosion can result in harmonic coupling between erosion and the Mediterranean sea level, providing an alternative mechanism for the cyclicity observed in early salt precipitation deposits and calling into question previous ideas regarding the timing of the events that occurred during the Messinian salinity crisis. [ABSTRACT FROM AUTHOR]

Published

2011

3. The evolution of the Danube gateway between Central and Eastern Paratethys (SE Europe): Insight from numerical modelling of the causes and effects of connectivity between basins and its expression in the sedimentary record

Author

Leever, K.A., Matenco, L., Garcia-Castellanos, D., and Cloetingh, S.A.P.L.

Subjects

*PALEOGEOGRAPHY, *NUMERICAL analysis, *SEDIMENTS, *SEDIMENTARY basins, *LITHOSPHERE, *SEA level, *MATHEMATICAL models

Abstract

Abstract: The Pannonian and Dacic Basins in SE Europe are presently connected by the Danube River across the South Carpathians, to which they are in a back-arc and foreland position respectively. Part of the Paratethys realm during the Neogene, open water communication between the basins was interrupted by the Late Miocene uplift of the Carpathians. Different mechanisms have been proposed for the formation of the Danube gateway: capture of the upstream lake or an upstream river or incision of an antecedent river. Estimates on its age range from Late Miocene to Quaternary. A related issue is the effect of the large Mediterranean sea level fall related to the Messinian Salinity Crisis on the Paratethys subbasins, specifically the “isolated” Pannonian Basin. In a synthetic numerical modelling study, using a pseudo-3D code integrating tectonics, surface processes and isostasy, we addressed the causes and effects of changes in connectivity between two large sedimentary basins separated by an elevated barrier. Specifically, we aimed to find the expression of connectivity events in the sedimentary record in general and the consequences for the evolution of the Pannonian–Dacic area in particular. We studied a range of parameters including the geometry and uplift rate of the barrier, downstream sea level change and lithosphere rigidity. We found that changes in connectivity are expressed in the sedimentary record through their effect on base level in the upstream basin and supply in the downstream basin. The most important factors controlling the response are the elevation difference between the basins and the upstream accommodation space at the time of reconnection. The most pronounced effect of reconnection through lake capture is predicted for a large elevation difference and limited upstream accommodation space. Downstream increase in sediment supply is dependent on the latter rather than the reconnection event itself. Of the parameters we tested, the rigidity of the lithosphere was found to be of major importance by its control on sediment loaded subsidence and generation of accommodation space. A downstream sea level change is unlikely to induce capture, but may affect the upstream lake level by enhancing incision in a pre-existing gateway. In the Pannonian–Dacic region, the mechanically weak, continuously subsiding Pannonian lithosphere allowed accommodation of significant volumes of continental sedimentation and as a consequence, transfer of excess sediment to the downstream Dacic Basin was only gradual. The Messinian sea level fall in the Dacic Basin could have been recorded in the Pannonian Basin only if a connection between the basins already existed. More detailed modelling of river incision taking into account lateral differences in erodibility in the South Carpathians will be required to give better time constraints on the formation of the Danube Gateway. [Copyright &y& Elsevier]

Published

2011

4. Probing connections between deep earth and surface processes in a land-locked ocean basin transformed into a giant saline basin: The Mediterranean GOLD project#.

Author

Rabineau, M., Cloetingh, S., Kuroda, J., Aslanian, D., Droxler, A., Gorini, C., Garcia-Castellanos, D., Moscariello, A., Burov, E., Sierro, F., Lirer, F., Roure, F., Pezard, P.A., Matenco, L., Hello, Y., Mart, Y., Camerlenghi, A., and Tripati, A.

Subjects

*GEOLOGICAL basins, *EARTH'S mantle, *LITHOSPHERE, *SEA level, *GLACIAL isostasy

Abstract

During the last decade, the interaction of deep processes in the lithosphere and mantle with surface processes (erosion, climate, sea-level, subsidence, glacio-isostatic readjustment) has been the subject of heated discussion. The use of a multidisciplinary approach linking geology, geophysics, geodesy, modelling, and geotechnology has led to the awareness of coupled deep and surface processes. Deep earth dynamics (topography, erosion, tectonics) are strongly connected to natural hazards such as earthquakes, landslides, and tsunamis; sedimentary mass transfers have important consequences on isostatic movements and on georesources, geothermal energy repartitions. The ability to read and understand the link between deep Earth dynamics and surface processes has therefore important societal impacts. Ground-truthing at carefully-selected sites of investigation is imperative to better understand these connections. Due to its youth (<30 Ma) and its subsidence history, the almost land-locked Gulf of Lion–Sardinia continental margins system provides a unique record of sedimentary deposition from the Miocene to present. Due to its high subsidence rate, palaeoclimatic variations, tectonic events and vertical evolution are all recorded here at very high resolution. The late Miocene isolation and desiccation of the Mediterranean, the youngest and most catastrophic event, the Messinian Salinity Crisis (MSC), induced drastic changes in marine environments: widespread deposition of evaporite (gypsum, anhydrite and halite) in the central basin, and intense subaerial erosion along its periphery. These extraordinary mass transfers from land to sea induced strong isostatic re-adjustments that are archived in the sedimentary record and represent a window to the lithospheric rheology and the deep processes. The GOLD (Gulf of Lion Drilling) project, proposes to explore this unique sedimentary record as well as the nature of the deep crustal structure, providing valuable information about the mechanisms underlying vertical motions in basins and their margins. [ABSTRACT FROM AUTHOR]

Published

2015

5. Magmatic pulse driven by sea-level changes associated with the Messinian salinity crisis

Author

Pietro Sternai, Thomas Edward Sheldrake, Luca Caricchi, Laurent Jolivet, Sébastien Castelltort, Daniel García-Castellanos, European Research Council, Sternai, P, Caricchi, L, Garcia-Castellanos, D, Jolivet, L, Sheldrake, T, and Castelltort, S

Subjects

Lithosphere, 010504 meteorology & atmospheric sciences, Evaporite, Desiccation mediterranean, Evolution, Earth science, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), Article, Paleontology, Volcanism, Extension, ddc:550, Pressure, Sea level, Migration, 0105 earth and related environmental sciences, Surface processes, Subduction, Mantle flow, Arc, Igneous rock, Magmatism, Subaerial, Constraints, General Earth and Planetary Sciences, Magma production, Earth and Planetary Sciences (all), Geology

Abstract

Between 5 and 6 million years ago, during the so-called Messinian salinity crisis, the Mediterranean basin became a giant salt repository. The possibility of abrupt and kilometre-scale sea-level changes during this extreme event is debated. Messinian evaporites could signify either deep-or shallow-marine deposits, and ubiquitous erosional surfaces could indicate either subaerial or submarine features. Significant and fast reductions in sea level unload the lithosphere, which can increase the production and eruption of magma. Here we calculate variations in surface load associated with the Messinian salinity crisis and compile the available time constraints for pan-Mediterranean magmatism. We show that scenarios involving a kilometre-scale drawdown of sea level imply a phase of net overall lithospheric unloading at a time that appears synchronous with a magmatic pulse from the pan-Mediterranean igneous provinces. We verify the viability of a mechanistic link between unloading and magmatism using numerical modelling of decompression partial mantle melting and dyke formation in response to surface load variations. We conclude that the Mediterranean magmatic record provides an independent validation of the controversial kilometre-scale evaporative drawdown and sheds new light on the sensitivity of magmatic systems to the surface forcing., P.S. is grateful to the Swiss NSF for providing funding for this project (Ambizione grant PZ00P2_168113/1). L.C. and T.E.S. were funded by the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement No. 677493-FEVER). D.G.-C. was funded by the MITE CGL2014-59516 (Spanish Government). S.C. was funded by Swiss NSF grant No. 200021-146822.

Published

2017