PLIOCENE-PLEISTOCENE SPELEOTHEM-BASED SEA LEVEL SNAPSHOTS FROM THE WESTERN MEDITERRANEAN

Abstract. Large positive and negative sea level anomalies at the coast of the Mediterranean Sea are linked to intensity and position of cyclones moving along the Mediterranean storm track, with dynamics involving different factors. This analysis is based on a model hindcast and considers nine coastal stations, which are representative of sea level anomalies with different magnitude and characteristics. When a shallow water fetch is present, the wind around the cyclone center is the main cause of sea level positive and negative anomalies, depending on its onshore or offshore direction. The inverse barometer effect produces a positive anomaly at the coast near the cyclone pressure minimum and a negative anomaly at the opposite side of the Mediterranean Sea, because a cross-basin mean sea level pressure gradient is associated to the presence of a cyclone. Further, at some stations, negative sea level anomalies are reinforced by a residual water mass redistribution within the basin, which is associated with a transient response to the atmospheric pressure forcing. Though the link between presence of a cyclone in the Mediterranean has comparable importance for positive and negative anomalies, the relation between cyclone position and intensity is stronger for the magnitude of positive events. Area of cyclogenesis, track of the central minimum and position at the time of the event differ depending on the location where the sea level anomaly occurs and on its sign. The western Mediterranean is the main cyclogenesis area for both positive and negative anomalies, overall. Atlantic cyclones mainly produce positive sea level anomalies in the western basin. At the easternmost stations, positive anomalies are caused by Cyclogenesis in the Eastern Mediterranean. North Africa cyclogeneses are a major source of positive anomalies at the central African coast and negative anomalies at the eastern Mediterranean and North Aegean coast.

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ENSURF: multi-model sea level forecast – implementation and validation results for the IBIROOS and Western Mediterranean regions

Ocean Science ◽

10.5194/os-8-211-2012 ◽

2012 ◽

Vol 8 (2) ◽

pp. 211-226 ◽

Cited By ~ 9

Author(s):

B. Pérez ◽

R. Brouwer ◽

J. Beckers ◽

D. Paradis ◽

C. Balseiro ◽

...

Keyword(s):

Real Time ◽

Sea Level ◽

Bayesian Model ◽

Weighted Average ◽

Western Mediterranean ◽

Bayesian Model Average ◽

Easy Access ◽

Visualization Tool ◽

Average Technique ◽

Model Average

Abstract. ENSURF (Ensemble SURge Forecast) is a multi-model application for sea level forecast that makes use of several storm surge or circulation models and near-real time tide gauge data in the region, with the following main goals: 1. providing easy access to existing forecasts, as well as to its performance and model validation, by means of an adequate visualization tool; 2. generation of better forecasts of sea level, including confidence intervals, by means of the Bayesian Model Average technique (BMA). The Bayesian Model Average technique generates an overall forecast probability density function (PDF) by making a weighted average of the individual forecasts PDF's; the weights represent the Bayesian likelihood that a model will give the correct forecast and are continuously updated based on the performance of the models during a recent training period. This implies the technique needs the availability of sea level data from tide gauges in near-real time. The system was implemented for the European Atlantic facade (IBIROOS region) and Western Mediterranean coast based on the MATROOS visualization tool developed by Deltares. Results of validation of the different models and BMA implementation for the main harbours are presented for these regions where this kind of activity is performed for the first time. The system is currently operational at Puertos del Estado and has proved to be useful in the detection of calibration problems in some of the circulation models, in the identification of the systematic differences between baroclinic and barotropic models for sea level forecasts and to demonstrate the feasibility of providing an overall probabilistic forecast, based on the BMA method.

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Archaeological Evidence for Eustatic Change of Sea Level and Earth Movements in the Western Mediterranean During the Last 2,000 Years

Geological Society of America Special Papers - Archaeological Evidence for Eustatic Change of Sea Level and Earth Movements in the Western Mediterranean During the Last 2,000 Years ◽

10.1130/spe109-p1 ◽

1969 ◽

pp. 1-98 ◽

Cited By ~ 30

Author(s):

N. C. Flemming

Keyword(s):

Sea Level ◽

Western Mediterranean ◽

Archaeological Evidence

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Changes in beach shoreline due to sea level rise and waves under climate change scenarios: application to the Balearic Islands (Western Mediterranean)

10.5194/nhess-2016-361 ◽

2016 ◽

Cited By ~ 1

Author(s):

Alejandra R. Enríquez ◽

Marta Marcos ◽

Amaya Álvarez-Ellacuría ◽

Alejandro Orfila ◽

Damià Gomis

Keyword(s):

Sea Level Rise ◽

Sea Level ◽

Climate Models ◽

Regional Climate ◽

Wave Climate ◽

Sandy Beaches ◽

Western Mediterranean ◽

Climate Change Scenarios ◽

Swash Zone ◽

Climate Scenarios

Abstract. In this work we assess the impacts in reshaping coastlines as a result of sea level rise and changes in wave climate. The methodology proposed combines the SWAN and SWASH wave models to resolve the wave processes from deep waters up to the swash zone in two micro-tidal sandy beaches in Mallorca Island, Western Mediterranean. In a first step, the modelling approach is validated with observations from wave gauges and from the shoreline inferred from video monitoring stations, showing a good agreement between them. Afterwards, the modelling setup is applied to the 21st century sea level and wave projections under two different climate scenarios, RCP45 and RCP85. Sea level projections were retrieved from state of the art regional estimates, while wave projections were obtained from regional climate models. Changes in the coastline are explored under mean and extreme wave conditions. Our results indicate that the studied beaches would suffer a coastal retreat between 7 and up to 50 m, equivalent to half of the present-day aerial beach surface, under the climate scenarios considered.

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An indurated Pleistocene coastal barrier on the inner shelf of the Gulf of Valencia (western Mediterranean): evidence for a prolonged relative sea-level stillstand

Geo-Marine Letters ◽

10.1007/s00367-012-0316-9 ◽

2012 ◽

Vol 33 (2-3) ◽

pp. 209-216 ◽

Cited By ~ 15

Author(s):

Javier Alcántara-Carrió ◽

Silvia Albarracín ◽

Isabel Montoya Montes ◽

Germán Flor-Blanco ◽

Ángela Fontán Bouzas ◽

...

Keyword(s):

Sea Level ◽

Western Mediterranean ◽

Inner Shelf ◽

Relative Sea Level ◽

Coastal Barrier

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Comment on “Sea level and climate changes during OIS 5e in the Western Mediterranean” by T. Bardají, J.L. Goy, J.L., C. Zazo, C. Hillaire-Marcel, C.J. Dabrio, A. Cabero, B. Ghaleb, P.G. Silva, J. Lario, Geomorphology 104 (2009), 22–37

Geomorphology ◽

10.1016/j.geomorph.2009.05.001 ◽

2009 ◽

Vol 110 (3-4) ◽

pp. 227-230 ◽

Cited By ~ 5

Author(s):

Barbara Mauz ◽

Fabrizio Antonioli

Keyword(s):

Sea Level ◽

Climate Changes ◽

Western Mediterranean

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QUANTIFYING THE VOLCANO-TECTONIC INFLUENCE ON HOLOCENE SEA-LEVEL EVOLUTION. A MULTIPROXY APPROACH ALONG THE MID-TYRRHENIAN COASTS (WESTERN MEDITERRANEAN)

10.1130/abs/2020am-355415 ◽

2020 ◽

Author(s):

Claudia Caporizzo ◽

◽

Gaia Mattei ◽

Giuseppe Corrado ◽

Matteo Vacchi ◽

...

Keyword(s):

Sea Level ◽

Western Mediterranean ◽

Multiproxy Approach ◽

Holocene Sea Level

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Repeated fluid expulsions during events of rapid sea-level rise in the Gulf of Lion, western Mediterranean Sea

BSGF - Earth Sciences Bulletin ◽

10.1051/bsgf/2017190 ◽

2017 ◽

Vol 188 (4) ◽

pp. 24 ◽

Cited By ~ 3

Author(s):

Aurélien Gay ◽

Thibault Cavailhès ◽

Dominique Grauls ◽

Bruno Marsset ◽

Tania Marsset

Keyword(s):

Sea Level Rise ◽

Mediterranean Sea ◽

Sea Level ◽

Western Mediterranean ◽

Unconsolidated Sediments ◽

Geometrical Parameters ◽

Near Surface ◽

Western Mediterranean Sea ◽

Gulf Of Lion ◽

Potential Fluid

Based on a High-Resolution 3D seismic block acquired in the Gulf of Lion in 2004–2005 we investigated fluid pipes and pockmarks on the top of the interfluve between the Hérault canyon and the Bourcart canyon both created by turbidity currents and gravity flows from the shelf to the deep basin in the north-western Mediterranean Sea. Combining the geometry of the potential fluid pipes with the induced deformation of surrounding sediments leads then to the ability to differentiate between potential fluid sources (root vs source) and to better estimate the triggering mechanisms (allochtonous vs. autochtonous cause). We linked together a set of derived attributes, such as Chaos and RMS amplitude, to a 3D description of pipes along which fluids may migrate. As previously shown in other basins, the induced deformation, creating cone in cone or V-shaped structures, may develop in response to the fluid pipe propagation in unconsolidated sediments in the near surface. The level at the top of a cone structure is diachronous. It means that stratigraphic levels over this surface are deformed at the end of the migration. They collapse forming a depression called a pockmark. These pipes are the result of repeated cycles of fluid expulsion that might be correlated with rapid sea-level rise instead of sediment loading. The most recent event (MIS 2.2 stage) has led to the formation of a pockmark on the modern seafloor. It has been used as a reference for calculating the effect of a rapid sea-level rise on fluid expulsion. As all physical and geometrical parameters are constrained, we were able to define that a + 34 m of sea level rise may account for triggering fluid expulsion from a very shallow silty-sandy layer at 9 m below seafloor since the last glacial stage. This value is consistent with a sea level rise of about 102 m during this period. This study shows that the episodic nature of fluid release resulted from hydromechanical processes during sea-level rise due to the interactivity between high pressure regimes and principal in situ stresses.

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