Search

Your search keyword '"Raad, Fadl"' showing total 25 results
Start Over Author "Raad, Fadl"
25 results on '"Raad, Fadl"'

4. A song of volumes, surfaces and fluxes: The case study of the Central Mallorca Depression (Balearic Promontory) during the Messinian Salinity Crisis

Author

Raad, Fadl, Ebner, Ronja, Heida, Hanneke, Meijer, Paul, Lofi, Johanna, Maillard, Agnès, Garcia-Castellanos, Daniel, Raad, Fadl, Ebner, Ronja, Heida, Hanneke, Meijer, Paul, Lofi, Johanna, Maillard, Agnès, and Garcia-Castellanos, Daniel

Abstract

The Central Mallorca Depression (CMD) located in the Balearic Promontory (Western Mediterranean) contains a well-preserved evaporitic sequence belonging to the Messinian Salinity Crisis (MSC) salt giant, densely covered by high- and low-resolution seismic reflection data. It has been proposed recently that the MSC evaporitic sequence in the CMD could be a non-deformed analogue of the key MSC area represented by the Caltanissetta Basin in Sicily. This presumed similarity makes the CMD an interesting system to better understand the MSC events. Physics-based box models of the water mixing between sub-basins, built on conservation of mass of water and salt, help constrain the hydrological conditions under which evaporites formed during the MSC. Those models have been widely used in the literature of the MSC in the past two decades. They have been mostly applied to the Mediterranean Sea as a whole focusing on the Mediterranean–Atlantic connection, or focusing on the influence of the Sicily Sill connecting the Western and Eastern Mediterranean Sea. In this study, we apply a downscaled version of such modelling technique to the CMD. First, we quantify the present-day volumes of the MSC units. We then use a reconstructed pre-MSC paleo-bathymetry to model salinity changes as a function of flux exchanges between the CMD and the Mediterranean. We show that a persistent connection between the CMD and the Mediterranean brine near gypsum saturation can explain volume of Primary Lower Gypsum under a sea level similar to the present. For the halite, on the contrary, we show that the observed halite volume cannot be deposited from a connected CMD-Mediterranean scenario, suggesting a drawdown of at least 850 m (sill depth) is necessary. Comparison between the deep basin halite volume and that of the CMD shows that it is possible to obtain the observed halite volume in both basins from a disconnected Mediterranean basin undergoing drawdown, although determining the average salinity

Published
2023

6. A song of volumes, surfaces and fluxes: The case study of the Central Mallorca Depression (Balearic Promontory) during the Messinian Salinity Crisis

Author

European Commission, Raad, Fadl, Ebner, R., Heida, Hanneke, Meijer, P., Lofi, J., Maillard, A., García-Castellanos, Daniel, European Commission, Raad, Fadl, Ebner, R., Heida, Hanneke, Meijer, P., Lofi, J., Maillard, A., and García-Castellanos, Daniel

Abstract

The Central Mallorca Depression (CMD) located in the Balearic Promontory (Western Mediterranean) contains a well-preserved evaporitic sequence belonging to the Messinian Salinity Crisis (MSC) salt giant, densely covered by high- and low-resolution seismic reflection data. It has been proposed recently that the MSC evaporitic sequence in the CMD could be a non-deformed analogue of the key MSC area represented by the Caltanissetta Basin in Sicily. This presumed similarity makes the CMD an interesting system to better understand the MSC events. Physics-based box models of the water mixing between sub-basins, built on conservation of mass of water and salt, help constrain the hydrological conditions under which evaporites formed during the MSC. Those models have been widely used in the literature of the MSC in the past two decades. They have been mostly applied to the Mediterranean Sea as a whole focusing on the Mediterranean–Atlantic connection, or focusing on the influence of the Sicily Sill connecting the Western and Eastern Mediterranean Sea. In this study, we apply a downscaled version of such modelling technique to the CMD. First, we quantify the present-day volumes of the MSC units. We then use a reconstructed pre-MSC paleo-bathymetry to model salinity changes as a function of flux exchanges between the CMD and the Mediterranean. We show that a persistent connection between the CMD and the Mediterranean brine near gypsum saturation can explain volume of Primary Lower Gypsum under a sea level similar to the present. For the halite, on the contrary, we show that the observed halite volume cannot be deposited from a connected CMD-Mediterranean scenario, suggesting a drawdown of at least 850 m (sill depth) is necessary. Comparison between the deep basin halite volume and that of the CMD shows that it is possible to obtain the observed halite volume in both basins from a disconnected Mediterranean basin undergoing drawdown, although determining the average salinity of

Published
2023

7. Petrophysical characterisation of a karstic carbonate aquifer, with implications for saltwater and brine intrusion into hydrothermal resources. The DEM'EAUX THAU project, Balaruc, France. 

Author

Pezard, Philippe, primary, Henry, Gilles, additional, Brun, Laurent, additional, Le Ber, Erwan, additional, Raad, Fadl, additional, Séranne, Michel, additional, Widhen, Florian, additional, Schleifer, Andrea, additional, Bellezza, Cinzia, additional, Meneghini, Fabio, additional, Brillouet, Nicolas, additional, Neyens, Denis, additional, and Lamotte, Claudine, additional

Published
2022
Full Text
View/download PDF

9. Plio-Quaternary strike-slip tectonics in the Central Mallorca Depression, Balearic Promontory: Land–sea correlation

Author

European Commission, García-Castellanos, Daniel [0000-0001-8454-8572], Heida, Hanneke [0000-0001-5456-896X], Maillard, Agnès, Raad, Fadl, Chanier, Frank, Heida, Hanneke, Lofi, Johanna, Mas, Guillem, García-Castellanos, Daniel, European Commission, García-Castellanos, Daniel [0000-0001-8454-8572], Heida, Hanneke [0000-0001-5456-896X], Maillard, Agnès, Raad, Fadl, Chanier, Frank, Heida, Hanneke, Lofi, Johanna, Mas, Guillem, and García-Castellanos, Daniel

Abstract

The Balearic Promontory (Spain) is of key importance to understand the tectonic kinematics of the westernmost Mediterranean, because its continued marine sedimentation has recorded the contrasting effects expected from competing geodynamic models proposed for the region. Near the center of this promontory, between the islands of Mallorca and Ibiza, the Miocene to Pleistocene stratigraphy of the Central Mallorca Depression presents an ideal record of the tectonic deformation that has received only limited attention. We use a widespread dataset of 2D seismic reflection profiles to identify, interpret and map the main prominent reflectors and extrapolate the thickness of the pre-Messinian and Pliocene-Quaternary sedimentary units. We then quantify the timing and style of deformation related to the various fault systems. Our results reveal for the first time a series of aligned small depressions bounded by extensional and strike-slip faults and filled with Plio-Quaternary sediment, perfectly aligned with the sub-basins of the onshore Mallorca Graben. A subsidence analysis confirms this correlation. We identify non-cylindrical deformation within the Plio-Quaternary unit that is remarkably similar to that observed onshore, suggesting continuous fault zones from the Central Mallorca Depression to Mallorca Island. We interpret an intra-PQ unconformity as the marker of a transition from extensional to strike-slip tectonic regime. The strike-slip stage is represented by both transpressional and transtensional structures, interpreted as restraining/releasing bends respectively and step overs along the faults. We show that these offshore faults in the Central Mallorca Depression overlap well with seismic epicenters and suggest major active strike-slip corridors that have an onshore continuity both until eastern Mallorca and in the southwestern Ibiza margin. The role of previous tectonic inherited structures (rifting, Betic thrusts, post-orogenic collapse) on the deformation rep

Published
2022

10. Flexural-isostatic reconstruction of the Western Mediterranean during the Messinian Salinity Crisis: Implications for water level and basin connectivity

Author

European Commission, Ministerio de Ciencia, Innovación y Universidades (España), García-Castellanos, Daniel [0000-0001-8454-8572], Heida, Hanneke [0000-0001-5456-896X], Jimenez-Munt, Ivone [0000-0003-4178-3585], Heida, Hanneke, Raad, Fadl, García-Castellanos, Daniel, Jimenez-Munt, Ivone, Maillard, Agnès, Lofi, J., European Commission, Ministerio de Ciencia, Innovación y Universidades (España), García-Castellanos, Daniel [0000-0001-8454-8572], Heida, Hanneke [0000-0001-5456-896X], Jimenez-Munt, Ivone [0000-0003-4178-3585], Heida, Hanneke, Raad, Fadl, García-Castellanos, Daniel, Jimenez-Munt, Ivone, Maillard, Agnès, and Lofi, J.

Abstract

During the Messinian Salinity Crisis (MSC, 5.97–5.33 Ma), thick evaporites were deposited in the Mediterranean Sea associated with major margin erosion. This has been interpreted by most authors as resulting from water level drop by evaporation but its timing, amplitude and variations between subbasins are poorly constrained due to uncertainty in post-Messinian vertical motions and lack of a clear time-correlation between the marginal basin and offshore records. The Balearic Promontory and surrounding basins exemplify a range of responses to this event, from margin erosion to up to a kilometre thick Messinian units in the abyssal areas containing the majority of the MSC halite. The Balearic Promontory contains unique patches of halite with thickness up to 325 m at intermediate depths that provide valuable information on water level during the stage of halite deposition. We compile seismic markers potentially indicating ancient shorelines during the drawdown phase: the first is marked by the transition from the MES to UU based on seismic data. The second is the limit between the bottom erosion surface (BES) and abyssal halite deposits. We restore these shorelines to their original depth accounting for flexural isostasy and sediment compaction. The best-fitting scenario involves a water level drop of ca. 1,100 ± 100 m for the Upper unit level and 1,500 ± 100 m for the BES level. According to our results, halite deposition began in the Central Mallorca Depression at 1,300–1,500 m depth, perched hundreds of metres above the deep basins, which were at 1,500–1,800 m (Valencia Basin) and >2,900 m (Algerian Basin). The hypothesis that erosion surfaces were formed subaerially during the drawdown phase is consistent with a model of halite deposition before/during the water level drop of at least 1,000 m, followed by the deposition of the Upper unit until the MSC is terminated by the reinstatement of normal marine conditions.

Published
2022

11. ‘SaltGiant’ drilling in the Sorbas Basin: Structural, Petrophysical and Geochemical characterization of the Messinian Salinity Crisis deposits

Author

Raad, Fadl, primary, Pezard, Philippe, additional, Viseras, Cesar, additional, Sierro, Francisco J., additional, Yeste, Luis M., additional, Aguila, Javier J., additional, Jerez, Paula, additional, Schleifer, Andrea, additional, Meneghini, Fabio, additional, Bellezza, Cinzia, additional, Lofi, Johanna, additional, Camerlenghi, Angelo, additional, and Aloisi, Giovanni, additional

Published
2022
Full Text
View/download PDF

12. Balearic Promontory architecture and history during the formation of the Mediterranean Salt Giant

Author

Raad, Fadl and STAR, ABES

Subjects
Basin analysis, Promontoire des Baléares, Seismic interpretation, [SDV.OT] Life Sciences [q-bio]/Other [q-bio.OT], Evaporites, Mediterranean Salt Giant (MSG), Géant salifère méditerranéen (MSG), Analyse de bassin, Messinian Salinity Crisis, Interprétation sismique, Balearic promontory, Crise de Salinité Messinienne, Évaporites
Abstract

The Messinian Salinity Crisis (MSC; 5.97– 5.33 Ma) is one of the most controversial geological events that influenced the evolution of the Mediterranean Basin in the late Miocene, leaving behind an immense volume of evaporites known as the Mediterranean Salt Giant (MSG). Today, more than 90% of the MSG evaporitic deposits are located offshore, buried below thick sediments that are Pliocene to Quaternary in age, and have thus been studied mainly by marine seismic reflection imaging. The Balearic Promontory (BP), a prominent topographic high in the Western Mediterranean basin, contains a unique and tectonically poorly deformed MSC record that resembles the evaporitic record of other peri-Mediterranean marginal and intermediate basins.This PhD thesis was performed in the framework of the SaltGiant European Training Network (ETN), a cross-disciplinary project whose objective is to understand the formation of the MSG. The work of the thesis is focused on the MSC deposits of the BP. Multi-disciplinary approach was applied to answer some of the still open questions concerning the MSC event. As a first step, seismic interpretation of a wide seismic reflection dataset in the Western Mediterranean in general and in the BP in particular was performed, with the aim of refining the mapping of the Messinian units covering the area. To restitute the depositional history of the MSC evaporites of the BP, a detailed comparison with the Messinian evaporitic units of the Sicilian Caltanissetta Basin was carried out, in which a discussion on how this history matches the existing 3-stages chrono-stratigraphic ‘consensus model’ is illustrated. The next step consisted in the restoration of the paleo-bathymetry of the BP at the beginning of the MSC, focusing on the relatively less-deformed basin located in the central part of the BP and called the Central Mallorca Depression (CMD). To achieve this restoration, structural interpretation in the CMD area was done where the main post-MSC tectonic-related vertical movements that altered the MSC paleo-bathymetry were identified. Then 2D and pseudo-3D backstripping analysis were applied in collaboration with other colleagues from the SaltGiant project, to restore the paleo-bathymetry. In the final step, the paleo-bathymetry was used to model the deposition of the MSC evaporite volumes observed in the CMD using physics-based models built on strait hydraulic-control theory. The results show that the MSC units of the CMD could constitute an undeformed analog of those outcropping on-land in the Sicilian Caltanissetta Basin. Moderate post-MSC deformation acted along MSC strike-slip corridors in the CMD following the MSC evaporites deposition, thus altering only locally the paleo-bathymetry. A high amplitude drawdown (>850m) is required during the halite stage of the MSC. The results rise a series of doubts about the current consensus model, still widely accepted. Doubts concern the synchronous onset of salt at the basin scale, the maximum depth of deposition of the Primary Lower Gypsum (PLG) and the timing of formation of the Resedimented Lower Gypsum (RLG). All the results and discussions hint to the need of revision of the current MSC consensus model, as well as the importance of initiating drillings offshore over the BP area, which would help revealing many of the mysteries still buried with the MSG., Entre 5.97 et 5.33Ma, à la fin du Miocène, un événement géologique exceptionnel aux conséquences majeures a affecté le bassin méditerranéen : la Crise de Salinité Messinienne (CSM). Cet épisode, dont le scénario exact reste encore énigmatique, est responsable du dépôt d’un volume considérable d’évaporites connu sous le nom de Géant Salifère de Méditerranée (GSM). Aujourd'hui, plus de 90 % des dépôts évaporitiques du MSG sont situés dans les bassins profonds de la Méditerranée et sont enfouis sous une épaisse couche de sédiments Plio- Quaternaire. Ces évaporites ont donc été étudiées principalement par imagerie sismique. Dans ce mémoire, nous nous intéressons aux dépôts de la crise enregistrés sur Promontoire des Baléares (BP), un haut topographique situé dans bassin de la Méditerranée occidentale. Du fait qu’il contient une succession de bassins en position intermédiaire stratégique, étagés entre les bassins marginaux du pourtour Méditerranéen et les bassins profonds, le BP se révèle un lieu unique avec des dépôts évaporitiques variés, ubiquistes et peu déformés tectoniquement, permettant d’accéder à une vision complète de l’enregistrement de la crise et pouvant mener à un scénario global cohérent.Cette thèse de doctorat a été réalisée dans le cadre d’un projet transdisciplinaire : « European Training Network (ETN) SaltGiant », dont l'objectif est de comprendre le GSM. Une approche pluridisciplinaire a été appliquée sur la zone d’étude choisie pour apporter des contraintes afin de répondre à certaines des nombreuses questions encore sans réponses sur la crise de salinité messinienne. Le travail de base a consisté en l'interprétation d'un large ensemble de données de sismique réflexion en Méditerranée occidentale, particulièrement concentré sur les dépôts messiniens du BP. Ceci a permis de préciser la cartographie des unités messiniennes de cette région et de définir leurs inter-relations géométriques. Une comparaison détaillée de ces unités évaporitiques avec celles du bassin messinien sicilien de Caltanissetta a été menée afin de reconstituer l'histoire de leur dépôt pour la confronter au modèle chrono-stratigraphique « consensuel » à trois phases. Pour reconstituer la paléo-bathymétrie de la dépression centrale de Majorque (CMD), le bassin le moins déformé situé dans sa partie centrale du BP, une interprétation structurale a permis d’identifier les principaux mouvements tectoniques post-MSC, modérés et localisés dans des corridors de décrochement. L'analyse par backstripping 2D et pseudo-3D, en collaboration avec d’autres collègues du projet SaltGiant, a alors permis de restaurer la paléo-bathymétrie de la CMD. Enfin, ces résultats ont été utilisés comme contraintes bathyétriques et de volumes pour modéliser le dépôt des évaporites observées, par des modèles physiques basés sur la théorie du contrôle hydraulique des détroits. Les résultats montrent que les unités messiniennes de la CMD pourraient constituer un analogue non déformé de celles qui affleurent à terre dans le bassin sicilien de Caltanissetta. Ils démontrent aussi qu'une baisse générale du niveau marin de grande amplitude (>850m) est nécessaire pour précipiter le volume de halite observé dans la CMD. Ces résultats, très bien contraints par ces études précises, remettent en cause certaines idées parfois encore largement acceptées. Ces doutes concernent en particulier l'apparition synchrone du sel à l'échelle du bassin méditerranéen, la profondeur maximale de dépôt du gypse inférieur primaire (PLG) et le moment de la formation du gypse inférieur resédimenté (RLG). En conclusion, ce mémoire montre la nécessité de réviser le scénario consensus actuel de la CSM, et l’importance de réaliser des forages en mer dans la région clef du BP, ce qui permettrait de révéler de nombreux mystères encore enfouis sous le géant salifère de Méditerranée.

Published
2022
Full Text
View/download PDF

13. Recent tectonics (post Messinian Salinity Crisis) in the Central Mallorca Depression, Balearic Promontory: Land–sea correlation

Author

Maillard, Agnès, Raad, Fadl, Chanier, Frank, Lofi, Johanna, Heida, Hanneka, Mas, Guillem, Géosciences Environnement Toulouse (GET), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), Laboratoire d’Océanologie et de Géosciences (LOG) - UMR 8187 (LOG), Institut national des sciences de l'Univers (INSU - CNRS)-Université du Littoral Côte d'Opale (ULCO)-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Nord]), Géosciences Montpellier, Institut national des sciences de l'Univers (INSU - CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Université des Antilles (UA), and SGF, CNRS, Laboratoire de Géologie de Lyon ou l’étude de la Terre, des planètes et de l’environnement

Subjects
[SDU]Sciences of the Universe [physics], Evaporites, Balearic Promontory, Strike, Central Mallorca Depression, ComputingMilieux_MISCELLANEOUS, slip deformation
Abstract

International audience

Published
2021

14. Freshening of the Mediterranean Salt Giant: controversies and certainties around the terminal (Upper Gypsum and Lago-Mare) phases of the Messinian Salinity Crisis

Author

Andreetto, Federico, Aloisi, Giovannni, Raad, Fadl, Heida, Hanneke, Flecker, Rachel, Agiadi, Konstantina, Lofi, Johanna, Blondel, Simon, Bulian, Francesca, Camerlenghi, Angelo, Caruso, Antonio, Ebner, Ronja, Garcia-Castellanos, Daniel, Gaullier, Virginie, Guibourdenche, Laetitia, Gvirtzman, Zohar, Hoyle, Tom, Meijer, Paul, Moneron, Jimmy, Sierro, Francisco J., Travan, Gaia, Tzevahirtzian, Athina, Vasiliev, Iuliana, Krijgsman, Wout, Paleomagnetism, Tectonophysics, Faculty of Geosciences, Utrecht University, Utrecht, Netherlands, Institut de Physique du Globe de Paris (IPGP), Institut national des sciences de l'Univers (INSU - CNRS)-IPG PARIS-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP), Géosciences Montpellier, Institut national des sciences de l'Univers (INSU - CNRS)-Université de Montpellier (UM)-Université des Antilles (UA)-Centre National de la Recherche Scientifique (CNRS), Andreetto F, Aloisi G, Raad F, Heida H, Flecker R, Agiadi K, Lofi J, Blondel S, Bulian F, Camerlenghi A, Caruso A, Ebner R, Garcia-Castellanos D, Gaullier V, Guibourdenche L, Gvirtzman Z, Hoyle TM, Meijer PT, Moneron JI, Sierro FJ, Travan G, Tzevahirtzian A, Vasiliev I, Krijgsman W, European Commission, García-Castellanos, Daniel [0000-0001-8454-8572], García-Castellanos, Daniel, Paleomagnetism, and Tectonophysics

Subjects
Mediterranean climate, 010504 meteorology & atmospheric sciences, Settore GEO/02 - Geologia Stratigrafica E Sedimentologica, Geochemistry, Mediterranean stratigraphy, Earth and Planetary Sciences(all), [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, Structural basin, engineering.material, Late Miocene, Messinian Salinity Crisis, 010502 geochemistry & geophysics, 01 natural sciences, Mediterranean Basin, Paratethy, Lago-Mare, Connectivity proxie, 14. Life underwater, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Paratethys, Brackish water, Terrigenous sediment, Messinian Salinity Crisi, Settore GEO/01 - Paleontologia E Paleoecologia, Settore GEO/08 - Geochimica E Vulcanologia, 13. Climate action, Paleogeography, Facies, engineering, General Earth and Planetary Sciences, Halite, Geology, Connectivity proxies
Abstract

The late Miocene evolution of the Mediterranean Basin is characterized by major changes in connectivity, climate and tectonic activity resulting in unprecedented environmental and ecological disruptions. During the Messinian Salinity Crisis (MSC, 5.97-5.33 Ma) this culminated in most scenarios first in the precipitation of gypsum around the Mediterranean margins (Stage 1, 5.97-5.60 Ma) and subsequently > 2 km of halite on the basin floor, which formed the so-called Mediterranean Salt Giant (Stage 2, 5.60-5.55 Ma). The final MSC Stage 3, however, was characterized by a "low-salinity crisis", when a second calcium-sulfate unit (Upper Gypsum; substage 3.1, 5.55-5.42 Ma) showing (bio)geochemical evidence of substantial brine dilution and brackish biota-bearing terrigenous sediments (substage 3.2 or Lago-Mare phase, 5.42-5.33 Ma) deposited in a Mediterranean that received relatively large amounts of riverine and Paratethys-derived low-salinity waters. The transition from hypersaline evaporitic (halite) to brackish facies implies a major change in the Mediterranean’s hydrological regime. However, even after nearly 50 years of research, causes and modalities are poorly understood and the original scientific debate between a largely isolated and (partly) desiccated Mediterranean or a fully connected and filled basin is still vibrant. Here we present a comprehensive overview that brings together (chrono)stratigraphic, sedimentological, paleontological, geochemical and seismic data from all over the Mediterranean. We summarize the paleoenvironmental, paleohydrological and paleoconnectivity scenarios that arose from this cross-disciplinary dataset and we discuss arguments in favour of and against each scenario., We thank the entire SALTGIANT community for many profitable workshops that inspired the development of this manuscript. This research was supported by the project SALTGIANT-Understanding the Mediterranean Salt Giant, a European project which has received funding from the European Union's Horizon 2020 research and innovation program, under the Marie Sklodowska-Curie [grant agreement No 765256

Published
2021
Full Text
View/download PDF

16. Freshening of the Mediterranean Salt Giant: controversies and certainties around the terminal (Upper Gypsum and Lago-Mare) phases of the Messinian Salinity Crisis

Author

Paleomagnetism, Tectonophysics, Andreetto, Federico, Aloisi, Giovannni, Raad, Fadl, Heida, Hanneke, Flecker, Rachel, Agiadi, Konstantina, Lofi, Johanna, Blondel, Simon, Bulian, Francesca, Camerlenghi, Angelo, Caruso, Antonio, Ebner, Ronja, Garcia-Castellanos, Daniel, Gaullier, Virginie, Guibourdenche, Laetitia, Gvirtzman, Zohar, Hoyle, Tom, Meijer, Paul, Moneron, Jimmy, Sierro, Francisco J., Travan, Gaia, Tzevahirtzian, Athina, Vasiliev, Iuliana, Krijgsman, Wout, Paleomagnetism, Tectonophysics, Andreetto, Federico, Aloisi, Giovannni, Raad, Fadl, Heida, Hanneke, Flecker, Rachel, Agiadi, Konstantina, Lofi, Johanna, Blondel, Simon, Bulian, Francesca, Camerlenghi, Angelo, Caruso, Antonio, Ebner, Ronja, Garcia-Castellanos, Daniel, Gaullier, Virginie, Guibourdenche, Laetitia, Gvirtzman, Zohar, Hoyle, Tom, Meijer, Paul, Moneron, Jimmy, Sierro, Francisco J., Travan, Gaia, Tzevahirtzian, Athina, Vasiliev, Iuliana, and Krijgsman, Wout

Published
2021

17. Freshening of the Mediterranean Salt Giant: controversies and certainties around the terminal (Upper Gypsum and Lago-Mare) phases of the Messinian Salinity Crisis

Author

European Commission, García-Castellanos, Daniel [0000-0001-8454-8572], Andreetto, F., Aloisi, G., Raad, Fadl, Heida, Hanneke, Flecker, Rachel, Agiadi, Konstantina, Blondel, S., Bulian, F., Camerlenghi, Angelo, Caruso, A., Ebner, R., García-Castellanos, Daniel, Gaullier, V., Guibourdenche, L., Gvirtzman, Z., Hoyle, T. M., Meijer, P. T., Moneron, J., Sierro, Francisco Javier, Travan, Gaia, Tzevahirtzian, A., Vasiliev, I., Krijgsman, W., European Commission, García-Castellanos, Daniel [0000-0001-8454-8572], Andreetto, F., Aloisi, G., Raad, Fadl, Heida, Hanneke, Flecker, Rachel, Agiadi, Konstantina, Blondel, S., Bulian, F., Camerlenghi, Angelo, Caruso, A., Ebner, R., García-Castellanos, Daniel, Gaullier, V., Guibourdenche, L., Gvirtzman, Z., Hoyle, T. M., Meijer, P. T., Moneron, J., Sierro, Francisco Javier, Travan, Gaia, Tzevahirtzian, A., Vasiliev, I., and Krijgsman, W.

Abstract

The late Miocene evolution of the Mediterranean Basin is characterized by major changes in connectivity, climate and tectonic activity resulting in unprecedented environmental and ecological disruptions. During the Messinian Salinity Crisis (MSC, 5.97-5.33 Ma) this culminated in most scenarios first in the precipitation of gypsum around the Mediterranean margins (Stage 1, 5.97-5.60 Ma) and subsequently > 2 km of halite on the basin floor, which formed the so-called Mediterranean Salt Giant (Stage 2, 5.60-5.55 Ma). The final MSC Stage 3, however, was characterized by a "low-salinity crisis", when a second calcium-sulfate unit (Upper Gypsum; substage 3.1, 5.55-5.42 Ma) showing (bio)geochemical evidence of substantial brine dilution and brackish biota-bearing terrigenous sediments (substage 3.2 or Lago-Mare phase, 5.42-5.33 Ma) deposited in a Mediterranean that received relatively large amounts of riverine and Paratethys-derived low-salinity waters. The transition from hypersaline evaporitic (halite) to brackish facies implies a major change in the Mediterranean’s hydrological regime. However, even after nearly 50 years of research, causes and modalities are poorly understood and the original scientific debate between a largely isolated and (partly) desiccated Mediterranean or a fully connected and filled basin is still vibrant. Here we present a comprehensive overview that brings together (chrono)stratigraphic, sedimentological, paleontological, geochemical and seismic data from all over the Mediterranean. We summarize the paleoenvironmental, paleohydrological and paleoconnectivity scenarios that arose from this cross-disciplinary dataset and we discuss arguments in favour of and against each scenario.

Published
2021

23. Flexural‐isostatic reconstruction of the Western Mediterranean during the Messinian Salinity Crisis: Implications for water level and basin connectivity.

Author

Heida, Hanneke, Raad, Fadl, Garcia‐Castellanos, Daniel, Jiménez‐ Munt, Ivone, Maillard, Agnès, and Lofi, Johanna

Subjects
*WATER levels, *SALINITY, *SEDIMENT compaction, *VERTICAL motion, *SALT, *RESERVOIR drawdown, *SHORELINE monitoring, *SHORELINES
Abstract

During the Messinian Salinity Crisis (MSC, 5.97–5.33 Ma), thick evaporites were deposited in the Mediterranean Sea associated with major margin erosion. This has been interpreted by most authors as resulting from water level drop by evaporation but its timing, amplitude and variations between subbasins are poorly constrained due to uncertainty in post‐Messinian vertical motions and lack of a clear time‐correlation between the marginal basin and offshore records. The Balearic Promontory and surrounding basins exemplify a range of responses to this event, from margin erosion to up to a kilometre thick Messinian units in the abyssal areas containing the majority of the MSC halite. The Balearic Promontory contains unique patches of halite with thickness up to 325 m at intermediate depths that provide valuable information on water level during the stage of halite deposition. We compile seismic markers potentially indicating ancient shorelines during the drawdown phase: the first is marked by the transition from the MES to UU based on seismic data. The second is the limit between the bottom erosion surface (BES) and abyssal halite deposits. We restore these shorelines to their original depth accounting for flexural isostasy and sediment compaction. The best‐fitting scenario involves a water level drop of ca. 1,100 ± 100 m for the Upper unit level and 1,500 ± 100 m for the BES level. According to our results, halite deposition began in the Central Mallorca Depression at 1,300–1,500 m depth, perched hundreds of metres above the deep basins, which were at 1,500–1,800 m (Valencia Basin) and >2,900 m (Algerian Basin). The hypothesis that erosion surfaces were formed subaerially during the drawdown phase is consistent with a model of halite deposition before/during the water level drop of at least 1,000 m, followed by the deposition of the Upper unit until the MSC is terminated by the reinstatement of normal marine conditions. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

24. Flexural-isostatic reconstruction of the Western Mediterranean vertical motions after the Messinian Salinity Crisis: implications for sea level and basin connectivity

Author

Heida, Hanneke, García-Castellanos, Daniel, Jimenez-Munt, Ivone, Raad, Fadl, Maillard, Agnès, Lofi, J., Heida, Hanneke, García-Castellanos, Daniel, Jimenez-Munt, Ivone, Raad, Fadl, Maillard, Agnès, and Lofi, J.

Abstract

The Messinian Salinity Crisis was a period of rapid and extreme environmental change in the Mediterranean occurring from 5.96 to 5.33 Ma, leading to deposition of a huge amount of evaporites in the deep basins and erosion on the margins. Erosional surfaces located deep below current sea level suggest a kilometric drop in sea level commonly associated with the deposition of massive halite deposits during the crisis. However, the timing and magnitude of this sea level drawdown are not well constrained in spite of its important implications for the conditions under which the different MSC sedimentary units were deposited and the connectivity of various subbasins during the crisis. A 2D (planform) flexural backstripping allows us to restore the Messinian topography in tectonically quiescent areas, constraining the isostatic subsidence due to the (post)Messinian sediment, and the potential effect of falling sea level during the crisis. In this way we restore the elevation of paleoshorelines and the original depth of erosional surfaces and other stratigraphic markers. We apply this method to the area spanning the Valencia Basin, Balearic Promontory and the Algero-Provençal Basin, to restore the Messinian Erosion Surfaces which formed subaerially during the drawdown to their original depth, constraining the minimum base level drop required to erode the margins at these locations. We reconstruct three key moments in the basin history: the pre-crisis basin, the end of halite deposition, and the end of the crisis. We consider multiple scenarios in terms of timing of sea level fall. Preliminary results indicate that over 1 km of sea level drop is required at the end of the Messinian, and over 2 km at the crisis acme to reproduce the observed location of the paleoshorelines, with only small sensitivity to crustal strength. This is in good agreement with estimates from previous backstripping investigations, and provides constraints on the progression of the MSC in the Western Me

Published
2020

25. Topography of the Balearic Promontory during the Messinian Salinity Crisis: Isostatic response to desiccation and evaporite deposition

Author

Heida, Hanneke, García-Castellanos, Daniel, Jimenez-Munt, Ivone, Maillard, Agnès, Lofi, J., and Raad, Fadl

Subjects
Mediterranean Sea, Geology, Messinian Salinity Crisis
Abstract

Topo-Europe Conference in Granada, Spain, 5–10 May 2019, The Messinian Salinity Crisis was a period of rapid and extreme environmental changes in the Mediterranean occurring from 5.96 to 5.33 Ma1¿, leading to deposition of a huge amount of evaporites in the deep basins and erosion on the margins. Erosional surfaces located deep below current sea level suggest a kilometric drop in base level commonly associated with the deposition of massive halite deposits at the `acme¿ of the crisis. However, the timing and magnitude of this sea level drawdown are not well constrained2¿, while this has important implications for the conditions under which the different MSC sedimentary units were deposited and the connectivity of various sub-basins during the crisis. Previous studies yield a sea level drop ranging from 400 m (Martínez et al. 2004) to 1500 m (Urgeles et al., 2010) for the Western Mediterranean, with values up to 2250 m reported for the Eastern Mediterranean. A pseudo 3-D (planform) flexural backstripping approach allows us to restore the Messinian topography in tectonically quiescent areas, estimating the isostatic subsidence due to the Plioquaternary sediment and restoring the elevation of paleoshorelines and the original depth of erosional surfaces and other stratigraphic markers.3¿ Here, we apply this method to the area spanning the Valencia Basin, Balearic Promontory and the Algero-Provençal Basin, to restore the Messinian Erosion Surface which formed above base level during the drawdown to its original elevation, constraining the minimum required base level drop for subaerial erosion at this elevation. Our results can be compared to previously obtained paleogeographies and checked for consistency with Messinian mammal migration onto the Balearic Islands (Mas et al., 2018).

Published
2019

Catalog

Books, media, physical & digital resources
See catalog results