Preservation of Modern and MIS 5.5 Erosional Landforms and Biological Structures as Sea Level Markers: A Matter of Luck?

Stefano Furlani,Renato Chemello,Valeria Lo Presti,Augusto Navone,Marco Taviani,Alice Busetti,Joanna Causon Deguara,Mauro Agate,Fiorenza Torricella,Egidio Trainito,Francesco Caldareri,Silas Dean,Sara Biolchi,Matteo Vacchi,Valeria Vaccher,Elisa Venturini,Ritienne Gauci,Fabrizio Antonioli,Fabio Canziani,Yuri Donno,Alessandro Porqueddu,Paolo Montagna,Chiara Boccali,Giacomo Deiana,Eleonora De Sabata,Paolo Orrù ,Thalassia Giaccone ,Elisa Dal Bò ,John Schembri

doi:10.3390/w13152127

Abstract

The Mediterranean Basin is characterized by a significant variability in tectonic behaviour, ranging from subsidence to uplifting. However, those coastal areas considered to be tectonically stable show coastal landforms at elevations consistent with eustatic and isostatic sea level change models. In particular, geomorphological indicators—such as tidal notches or shore platforms—are often used to define the tectonic stability of the Mediterranean coasts. We present the results of swim surveys in nine rocky coastal sectors in the central Mediterranean Sea using the Geoswim approach. The entire route was covered in 22 days for a total distance of 158.5 km. All surveyed sites are considered to have been tectonically stable since the last interglacial (Marine Isotope Stage 5.5 [MIS 5.5]), because related sea level markers fit well with sea level rise models. The analysis of visual observations and punctual measurements highlighted that, with respect to the total length of surveyed coast, the occurrence of tidal notches, shore platforms, and other indicators accounts for 85% of the modern coastline, and only 1% of the MIS 5.5 equivalent. Therefore, only 1% of the surveyed coast showed the presence of fossil markers of paleo sea levels above the datum. This significant difference is mainly attributable to erosion processes that did not allow the preservation of the geomorphic evidence of past sea level stands. In the end, our research method showed that the feasibility of applying such markers to define long-term tectonic behaviour is much higher in areas where pre-modern indicators have not been erased, such as at sites with hard bedrock previously covered by post-MIS 5.5 continental deposits, e.g., Sardinia, the Egadi Islands, Ansedonia, Gaeta, and Circeo. In general, the chances of finding such preserved indicators are very low.

Highlights

Sea level rise and fall are due to planetary-scale processes, and constitute one of the major climate-driven effects on the coastal landscape
Regarding Modern Tidal Notches (MTNs) and Fossil Tidal Notches (FTNs), we evaluated the extent of these landforms from field observations and the image dataset collected during the swim campaigns
Modern Shore Platforms (MSPs) were almost absent in our sites because very few useful data on sea level change can be collected from these types of coasts

Summary

Introduction

Sea level rise and fall are due to planetary-scale processes, and constitute one of the major climate-driven effects on the coastal landscape. Tectonic movements are significant along the coasts of the Mediterranean Sea, due to the active tectonism in many parts of the basin [1]—the latter shaped by geological and geomorphological processes driven by changes in sea level over millions of years [1]. About 60% of the Mediterranean Basin is bordered by rocky coasts [2], which are characterised by landforms related to paleo sea levels, such as tidal notches, marine terraces, vermetid reefs, etc. Fossil markers of former sea levels provide fundamental information related to changes in climate during glacial and interglacial periods, regional ice-sheet variations, rate and geographic source of meltwater influx, as well as on the rheological structure of the solid Earth—a key parameter for understanding mantle flow and the tectonic evolution of our planet (e.g., [6,7,8]).

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Conclusion