Shallow Off-Shore Archaeological Prospection with 3-D Electrical Resistivity Tomography: The Case of Olous (Modern Elounda), Greece

It is well known that nowadays as well as in the past the vast majority of human habitation and activities are mainly concentrated in littoral areas. Thus the increased attention to coastal zone management contributed to the development and implementation of shallow-water mapping approaches for capturing current environmental conditions. During the last decade, geophysical imaging techniques like electrical resistivity tomography (ERT) have been used in mapping onshore buried antiquities in a non-destructive manner, contributing to cultural heritage management. Despite its increased implementation in mapping on-shore buried archaeological remains, ERT has minimal to non-existent employment for the understanding of the past dynamics in littoral and shallow off-shore marine environments. This work presents the results of an extensive ERT survey in investigating part of the Hellenistic to Byzantine submerged archaeological site of Olous, located on the north-eastern coast of Crete, Greece. A marine area of 7100 m2 was covered with 178 densely spaced ERT lines having a cumulative length of 8.3 km. A combination of submerged static and moving survey modes were used to document potential buried and submerged structures. The acquired data from the marine environment were processed with two-dimensional and three-dimensional inversion algorithms. A real time kinematic global navigation satellite system was used to map the visible submerged walls and compile the bathymetry model of the bay. The adaptation of ERT in reconstructing the underwater archaeological remains in a shallow marine environment presented specific methodological and processing challenges. The in situ experience from the archaeological site of Olous showed that ERT provided a robust method for mapping the submerged archaeological structures related to the ancient built environment (walls, buildings, roads), signifying at the same time the vertical stratigraphy of the submerged sediments. The inherent limitation of employing ERT in a conductive environment is counterbalanced by the incorporation of precise knowledge for the conductivity and bathymetry of the saline water in the modelling and inversion procedure. Although the methodology definitely needs further refinement, the overall outcomes of this work underline the potential of ERT imaging being integrated into wider shallow marine projects for the mapping of archaeological sites in similar environmental regimes.

[1]  Apostolos Sarris,et al.  Geophysical and related techniques applied to archaeological survey in the Mediterranean: a review , 2000 .

[2]  N. K. Pavlis,et al.  The development and evaluation of the Earth Gravitational Model 2008 (EGM2008) , 2012 .

[3]  Mahmut Okyar,et al.  Continuous resistivity profiling survey in Mersin Harbour, Northeastern Mediterranean Sea , 2013, Marine Geophysical Research.

[4]  Chris Gaffney,et al.  DETECTING TRENDS IN THE PREDICTION OF THE BURIED PAST : A REVIEW OF GEOPHYSICAL TECHNIQUES IN ARCHAEOLOGY , 2008 .

[5]  Oliver Kuras,et al.  Recent developments in the direct-current geoelectrical imaging method , 2013 .

[6]  Avner Raban,et al.  Marine Magnetic Survey of a Submerged Roman Harbour, Caesarea Maritima, Israel , 2004 .

[7]  Elias Fakiris,et al.  A MARINE GEOARCHAEOLOGICAL SURVEY, CAPE SOUNION, GREECE: PRELIMINARY RESULTS , 2014 .

[8]  Torleif Dahlin,et al.  Detection and Characterization of Fracture Zones in Bedrock - Possibilities and Limitations , 2014 .

[9]  T. Dahlin,et al.  Continuous electrical imaging for mapping aquifer recharge along reaches of the Namoi River in Australia , 2009 .

[10]  Salvatore Passaro,et al.  Marine electrical resistivity tomography for shipwreck detection in very shallow water: a case study from Agropoli (Salerno, southern Italy) , 2010 .

[11]  Luca Cocchi,et al.  Marine Archaeogeophysical Prospection of Roman Salapia Settlement (Puglia, Italy): Detecting Ancient Harbour Remains , 2012 .

[12]  N. Linford The application of geophysical methods to archaeological prospection , 2006 .

[13]  M. Loke,et al.  Inversion of Data from Electrical Resistivity Imaging Surveys in Water-Covered Areas , 2004 .

[14]  Lee Slater,et al.  Aquatic electrical resistivity imaging of shallow-water wetlands , 2007 .

[15]  V. Kapsimalis,et al.  Searching for Ancient Shipwrecks in the Aegean Sea: the Discovery of Chios and Kythnos Hellenistic Wrecks with the Use of Marine Geological‐Geophysical Methods , 2007 .

[16]  Joseph I. Boyce,et al.  Ultra-high-resolution marine 2D–3D seismic investigation of the Liman Tepe/Karantina Island archaeological site (Urla/Turkey) , 2009 .

[17]  Cesare Comina,et al.  Waterborne and on-land electrical surveys to suggest the geological evolution of a glacial lake in NW Italy , 2014 .

[18]  T. Dahlin,et al.  A comparison of smooth and blocky inversion methods in 2D electrical imaging surveys , 2001 .

[19]  Maurizio Fedi,et al.  Magnetic survey at the submerged archaeological site of Baia, Naples, southern Italy , 2005 .

[20]  N. Papadopoulos,et al.  Archaeological investigations in the shallow seawater environment with electrical resistivity tomography , 2015 .