Abstract
A marine geological-geophysical survey of selected areas on the Saudi Arabian continental shelf of the Farasan Archipelago in the southeastern Red Sea has been conducted in the framework of the ERC-funded DISPERSE project. The aim was to explore systematically the geological, tectonic and sedimentary structure of the shelf and provide insights into the submerged prehistoric landscapes. The survey targeted features believed to be of significance in relation to the archaeological potential of the submerged landscape, including geological structure, palaeoenvironment, and sea-level change. Swath bathymetry, seismic and subbottom profiling data, side scan sonar imaging and sediment coring indicate that the flat areas belonging to the 70–90 m deep shelf may have developed as part of an erosive marine terrace during the latter part of MIS 3, between 30 and 45 ka BP. A second terrace lying at 115–120 m water-depth is associated with MIS 2, whereas a third one, mapped at about 40 m water-depth, may correspond to the MIS 5.1 period, 80–85 ka BP. Extensional tectonics, possibly driven by basin-ward flow of underlying Miocene evaporites below the shelf, is responsible for the rupturing of the latter along NW–SE trending faults. The resulting fault-bounded blocks, which are composed of Plio-Quaternary rocks, were dragged and drifted away from the shelf edge to create isolated flat-topped ridges surrounded by steep slopes and troughs. The largest part of the shelf along with the 90 m deep, flat tops of the ridges were exposed when the sea-level was at 115–120 m bpsl (below present sea level) during the Last Glacial Maximum (LGM). This geomorphological configuration may also be valid for the previous low sea-level period, 140 ka BP (MIS 6). Shallow and deep depressions and valleys on the main terrace of the shelf, which formed by solution of evaporite diapirs or domes, were permanent or ephemeral lakes when the shelf was exposed during MIS 2. Similar lakes possibly formed in the many deep sinkholes which occur on the available hydrographic charts along the 120 km wide and several-hundred-km long Farasan shelf. Finally, the presence of valleys and canyons on the seafloor of the survey areas indicates erosion of the shelf under subaerial conditions due to surface water-flow.
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References
Abou Ouf MA, El-Shater A (1992) Sedimentology and mineralogy of Jizan shelf sediments, Red Sea, and Saudi Arabia. J King Abdulaziz Univ Marine Sci Jeddah 3:39–54
Armitage SJ, Jasim SA, Marks AE, Parker AG, Usik VI, Uerpmann H-P (2011) The southern route “Out of Africa”: evidence for an early expansion of modern humans into Arabia. Science 331:453–456
Augustin N, Devey CW, van der Zwan FM, Feldens P, Tominaga M, Bantan RA, Kwasnitschka T (2014) The rifting to spreading transition in the Red Sea. Earth Planet Sci Lett 395:217–230
Augustin N, Devey N, van der Zwan F (this volume) A modern view on the Red Sea Rift: tectonics, volcanism and salt blankets
Bailey GN, Flemming NC (2008) Archaeology of the continental shelf: Marine resources, submerged landscapes and underwater archaeology. Quat Sci Rev 27:2153–2165
Bailey GN, King GCP (2011) Dynamic landscapes and human dispersal patterns: tectonics, coastlines and the reconstruction of human habitats. Quatern Sci Rev 30:1533–1553
Bailey GN, Sakellariou D (2012) SPLASHCOS: Submerged Prehistoric Archaeology and Landscapes of the Continental Shelf. Antiquity 86(334). http://antiquity.ac.uk/projgall/sakellariou334/
Bailey GN, King GCP, Flemming NC, Lambeck K, Momber G, Moran LJ, Al-Sharekh AM, Vita-Finzi C (2007) Coastlines, submerged landscapes and human evolution: The Red Sea Basin and the Farasan Islands. J Island Coastal Archaeology 2:127–160
Bailey GN, King GCP, Devès M, Hausmann N, Inglis R, Laurie E, Meredith-Williams M, Momber G, Winder I, Alsharekh A, Sakellariou D (2012) DISPERSE: dynamic landscapes, coastal environments and human dispersals. Antiquity 86(334). http://antiquity.ac.uk/projgall/bailey334/
Bailey GN, Reynolds SC, King GCP (2011) Landscapes of human evolution: models and methods of tectonic geomorphology and the reconstruction of hominin landscapes. J Human Evolution 60(3):257–280
Bailey GN, Devès MH, Inglis RH, Meredith-Williams MG, Momber G, Sakellariou D, Sinclair AGM, Rousakis G, Al Ghamdi S, Alsharekh AM (2015) Blue Arabia: Palaeolithic and underwater survey in SW Saudi Arabia and the role of coasts in Pleistocene dispersal. Quatern Int 382:42–57. https://doi.org/10.1016/j.quaint.2015.01.002
Bailey G, Meredith-Williams M, Alsharekh A, Hausmann N (this volume) The archaeology of Pleistocene coastal environments and human dispersals in the Red Sea: Insights from the Farasan Islands
Bantan RA (1999) Geology and sedimentary environments of Farasan Bank (Saudi Arabia) southern Red Sea: A combined remote sensing and field study. Ph.D. Thesis, Department of Geology, Royal Holloway, University of London, January 1999
Bayer HJ, Hotzl H, Jado AR, Roscher B, Voggenreiter W (1988) Sedimentary and structural evolution of the northwest Arabian Red Sea Margin. Tectonophysics 153:136–151
Bosence DWJ (1998) Stratigraphic and sedimentological models of rift basins. In: Purser BH, Bosence DWJ (eds) Sedimentation and tectonics in Rift basins: Red Sea-Gulf of Aden. Chapman & Hall, London, pp 9–25
Bosworth W, Huchon P, McClay K (2005) The Red Sea and Gulf of Aden Basins. J African Earth Sci 43:334–378
Bosworth W (2015) Geological evolution of the Red Sea: Historical background, review, and synthesis. In: Rasul NMA, Stewart ICF (eds) The Red Sea. Springer Earth System Sciences, Springer-Verlag Berlin Heidelberg, pp 45–78. https://doi.org/10.1007/978-3-662-45201-1_1
Carbone F, Matteucci R, Angelucci A (1998) Present day sedimentation of the carbonate platform of the Dahlak Islands, Eritera. In: Purser BH, Bosence DWJ (eds) Sedimentation and tectonics in Rift basins, Red Sea-Gulf of Aden. Chapman & Hall, London, pp 523–536
Cochran JR (1983) A model for development of the Red Sea. Bull Am Assoc Petrol Geologists 67:41–69
Dabbagh A, Hoetzl H, Schnier H (1984) Farasan Islands. In: Jado AR, Zöttl (eds) Quaternary Period in Saudi Arabia. Springer, Wien, pp 212–220
Delagnes A, Tribolo C, Bertran P, Brenet M, Rémy C, Laubert J, Khalidi L, Mercier N, Nomade S, Peigne S, Sitzia L, Tourne-Piche J-F, Al-Halibi M, Al-Mosabi A, Macchiarelli R (2012) Inland human settlement in southern Arabia 55,000 years ago. New evidence from the Wadi Surdud Middle Paleolithic site complex, western Yemen. J Human Evolution 63(3):452–474
Dixon JE, Monteleone K (2014) Gateway to the Americas: Underwater archaeological survey in Beringia and the North Pacific. In: Evans A, Flemming N, Flatman J (eds) Prehistoric Archaeology of the Continental Shelf: A Global Review. Springer, New York, pp 95–114
Dullo WC (1990) Facies, fossil record and age of Pleistocene reefs from the Red Sea (Saudi Arabia). Facies 22:1–46
Dullo WC, Blomeier D, Camoin GF, Casanova J, Colonna M et al (1997) Morphological evolution and sedimentary facies on the fore-slopes of Mayotte, Comoro Island: Direct observations from submarine. In: Camsin G, Bergerson D (eds) Carbonate Platforms of the Indian Ocean and the Pacific. IAS Special Publication
Dullo WC, Montaggioni L (1998) Modern Red Sea coral reefs: A review of their morphologies and zonation. In: Purser BH, Bosence DWJ (eds) Sedimentation and Tectonics in Rift Basins: Red Sea-Gulf of Aden. Chapman & Hall, London, pp 583–594
Faure H, Walter RC, Grant DR (2002) The coastal oasis: Ice age springs on emerged continental shelves. Global Planetary Change 33:47–56
Feldens P, Mitchell NC (2015) Salt flows in the central Red Sea. In: Rasul NMA, Stewart ICF (eds) The Red Sea: the formation, morphology, oceanography and environment of a young ocean basin. Springer Earth System Sciences, Berlin Heidelberg, pp 205–218. https://doi.org/10.1007/978-3-662-45201-1_1
Geraga M, Sergiou S, Sakellariou D (this volume) Preliminary results of micropaleontological analyses on sediment core FA09 from the southern Red Sea continental shelf
Girdler RW, Styles P (1974) Two stage sea-floor spreading. Nature 247:7–11
Gvirtzman G (1994) Fluctuations of sea level during the past 400,000 years: the record of Sinai, Egypt (Northern Red Sea). Coral Reefs 13:203–214
Hudec MR, Jackson MPA (2007) Terra infirma: Understanding salt tectonics. Earth-Sci Rev 82:1–28
Hughes GW, Beydoun ZR (1992) The Red Sea-Gulf of Aden: Biostratigraphy, lithostratigraphy and palaeoenvironments. J Petrol Geol 15:135–156
Inglis RH, Bosworth W, Rasul N, Al Saeedi A, Bailey G (this volume) Investigating the palaeoshorelines and coastal archaeology of the southern Red Sea
King GCP, Bailey GN (2006) Tectonics and human evolution. Antiquity 80:265–286
LaBreque JL, Zitellini N (1985) Continuous sea-floor spreading in Red Sea, an alternative interpretation of magnetic anomaly pattern. Bull Am Assoc Petrol Geol 69:513–524
Lambeck K, Purcell A, Flemming N, Vita-Finzi C, Alsharekh A, Bailey GN (2011) Sea level and shoreline reconstructions for the Red Sea: Isostatic and tectonic considerations and implications for hominin migration out of Africa. Quatern Sci Rev 30:3542–3574
Macaulay V, Hill C, Achilli A, Rengo C, Clarke D, Meehan W, Blackburn J, Semino O, Scozzari R, Cruciani F, Taha A, Shaari NK, Raja JM, Ismail P, Zainuddin Z, Goodwin W, Bulbeck D, Bandelt HJ, Oppenheimer S, Torroni A, Richards M (2005) Single, rapid coastal settlement of Asia revealed by analysis of complete mitochondrial genomes. Science 308:1034–1036
Mellars P (2006) Why did modern populations disperse from Africa ca. 60,000 years ago? A new model. Proc Nat Acad Sci USA 103:9381–9386
Mideast Industries Ltd. (1966) Salt production possibilities of the Jizan and Farasan Island area. Saudi Arabian Directorate General for Mineral Resource Report DGMR-279, 13 pp
Mitchell DJW, Allen RB, Salama W, Abduzakm A (1992) Tectonostratigraphic framework and hydrocarbon potential of the Red Sea. J Petrol Geol 15(2):187–210
Petraglia MD, Rose JI (eds) (2009) The evolution of human populations in Arabia. Springer, Dordrecht
Petraglia MD, Alsharekh AM, Crassard E, Drake NA, Groucutt H, Parker AG, Roberts RG (2011) Middle Paleolithic occupation on a Marine Isotope Stage 5 lakeshore in the Nefud Desert. Saudi Arabia. Quatern Sci Rev 30(13–14):1555–1559
Petraglia MD, Breeze PS, Groucutt HS (this volume) Blue Arabia, Green Arabia: Examining human colonisation and dispersal models
Purser BH, Bosence DWJ (1999) Sedimentation and tectonics in rift basins: Red Sea-Gulf of Aden. Chapman & Hall, London
Roeser HA (1975) A detailed magnetic survey of the southern Red Sea. Geol. Jb. D13:131–153
Rohling EJ, Fenton M, Jorissen FJ, Bertrand P, Ganssen G, Caulet JP (1998) Magnitudes of sea-level lowstands of the past 500,000 years. Nature 394:162–165
Rohling EJ, Grant K, Bolshaw M, Roberts AP, Siddall M, Hemleben C, Kucera M (2009) Antarctic temperature and global sea level closely coupled over the past five glacial cycles. Nat Geosci 2:500–504
Rohling EJ, Grant KM, Roberts AP, Larrasoaña JC (2013) Paleoclimate variability in the Mediterranean and Red Sea regions during the last 500,000 years: Implications for hominin migrations. Curr Anthropol 54(S8):S183–S201. https://doi.org/10.1086/673882
Rose JI, Usik V, Marks A, Hilbert Y, Galleti C, Parton A, Geiling JM, V. Cerné V, Morley M, Roberts R (2011) The Nubian complex of Dhofar, Oman: an African Middle Stone Age industry in southern Arabia. PLoS ONE 6(11):e28239. https://doi.org/10.1371/journal.pone.0028239
Sanderson D, Kinnaird T (this volume) Optically Stimulated Luminescence dating as a geochronological tool for Late Quaternary sediments in the Red Sea region
Schmidt DL, Hadley DG, Brown GF (1982) Middle Tertiary continental rift and evolution of the Red Sea in south-western Saudi Arabia. Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources, Jeddah, USGS-OF-03-6, 56 pp
Searle RC, Ross DA (1975) A geophysical study of the Red Sea axial trough between 20.5 and 22 N. Geophys J Roy Astron Soc 43:555–572
Siddall M, Smeed DA, Hemleben C, Rohling EJ, Schmelzer I, Peltier WR (2004) Understanding the Red Sea response to sea level. Earth Planet Sci Lett 225:421–434
Stoffers P, Kuhn R (1974) Red Sea evaporites - A petrographic and geochemical study. In: Whitmarsh RB, Weser OE, Ross DA (eds) Initial reports of the Deep Sea Drilling Project, vol. 23. U. S. Government. Printing Office, Washington, pp 821–847
Stoffers P, Ross DA (1977) Sedimentary history of the Red Sea. In: Hilpert LS (ed) Red Sea Research 1970–1975. Saudi Arabian Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources, Jeddah, Bulletin 22, pp i–iv and H1–H19
Walter RC, Buffler RT, Bruggemann JJ, Guillaume MMM, Berhe SM, Negassi B, Libsekal Y, Cheng H, Edwards RL, Von Gosel R, Neradeau D, Gagnon M (2000) Early human occupation of the Red Sea coast of Eritrea during the Last Interglacial. Nature 405:65–69
Acknowledgements
We thank the Saudi Commission for Tourism and National Heritage (SCTH) for permission to undertake fieldwork, and the President, HRH Prince Sultan bin Salman bin AbdulAziz al Saud, the Vice-President, Professor Ali Al-Ghassan, and the Director General, Jamal al Omar, for their support of our research. We also thank HRH King Salman bin Abul Aziz Al Saud, formerly Crown Prince and Minister of Defense, and the Hydrographic Department of the Saudi Ministry of Defense, for permission to undertake the cruise of R/V AEGAEO. We also thank Lt. Fahad Al Shwish, Observer from the Hydrographic Department of the Saudi Ministry of Defense, for his support and valuable assistance in overcoming unexpected logistical difficulties during the cruise, and Captain Theodoros Kanakaris and the crew of R/V AEGAEO for their untiring efforts to ensure the smooth running of the scientific operation during the offshore survey work. The research is funded by the European Research Council through Advanced Grant 269586 DISPERSE under the ‘Ideas’ Specific Programme of the Seventh Framework Programme. This is DISPERSE contribution no. 43.
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Sakellariou, D., Rousakis, G., Panagiotopoulos, I., Morfis, I., Bailey, G.N. (2019). Geological Structure and Late Quaternary Geomorphological Evolution of the Farasan Islands Continental Shelf, South Red Sea, SW Saudi Arabia. In: Rasul, N., Stewart, I. (eds) Geological Setting, Palaeoenvironment and Archaeology of the Red Sea. Springer, Cham. https://doi.org/10.1007/978-3-319-99408-6_28
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