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Quaternary Stratigraphy and Paleogeography of the Galilee Coastal Plain, Israel

Published online by Cambridge University Press:  20 January 2017

Dorit Sivan ,
Gedaliahu Gvirtzman  and
Eytan Sass
Dorit Sivan
Affiliation:
Department of Maritime Civilizations, Haifa University, Haifa, 31905, Israel
Gedaliahu Gvirtzman
Affiliation:
Department of Geography, Bar-Ilan University, Ramat-Gan, 52900, Israel
Eytan Sass
Affiliation:
Institute of Earth Sciences, The Hebrew University of Jerusalem, Jerusalem, 91904, Israel
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Abstract

The Quaternary deposits in the Galilee coastal plain comprise alternating calcareous sandstone, red loam, dark clay, and uncemented sand. The calcareous sandstone in the lower part of the sequence represents a Pliocene to early Pleistocene marine transgression, and is covered unconformably by the late Quaternary sequence. The base of this sequence has an estimated age of ∼500,000 yr. It is covered unconformably by marine calcareous sandstone in the west, which represents the global high sea-level stand of isotope stage 7.1, and is known as one of the “Tyrrhenian” events in the Mediterranean area. The overlying members represent the low sea-level stand of stage 6, the first a red paleosol indicating a relatively wet phase and the second an eolianite unit representing a drier phase. The eolianite forms longitudinal, subparallel ridges that formed contemporaneously. The overlying marine sandstone, which contains one of the diagnostic fossils of the “Tyrrhenian” events, the gastropodStrombus buboniusLMK, accumulated during the global high stand of stage 5.5. The last glacial period left no sedimentary record. The Holocene is represented by a marine clay unit that is covered by sand. The present study establishes a complete and detailed chronostratigraphic sequence for an eastern Mediterranean beach, which contains the gastropodS. buboniusLMK.S. buboniuson the Galilee coast is attributed to stage 5.5 and therefore, establishes an east–west Mediterranean correlation, which can be used for linking Mediterranean events to paleo-sea levels and global climate changes.

Type
Original Articles
Information
Quaternary Research , Volume 51 , Issue 3 , May 1999 , pp. 280 - 294
Copyright
University of Washington

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References

Avnimelech, M., (1943). On the geology of the coastal plain of Israel: Nahariyya suburb. Yediot (Bulletin of the Israel Exploration Society) 10, 3946.Google Scholar
Bard, E., Hamelin, B., Fairbanks, R.G., (1990). U-Th ages obtained by mass spectrometry in corals from Barbados: Sea level during the last 130,000 years. Nature 346, 456458.Google Scholar
Bloom, A.L., Broecker, W.S., Chappell, J.M.A., Matthews, R.K., Mesolella, K.J., (1974). Quaternary sea level fluctuations on a tectonic coast: New230 234 . Quaternary Research 4, 185205.CrossRefGoogle Scholar
Broecker, W.S., Thurber, D.L., Goddard, J., Ku, T.L., Matthews, R.K., Mesolella, K.J., (1968). Milankovitch hypothesis supported by precise dating of coral reefs and deep-sea sediments. Science 159, 297300.Google Scholar
Buchbinder, B., (1975). Lithogenesis of Miocene reef limestones in Israel with particular reference to the significance of the red algae. Geological Survey of Israel Report OD/3/75.Google Scholar
Chappell, J., Shackleton, N.K., (1986). Oxygen isotopes and sea level. Nature 324, 137140.Google Scholar
Dai Pra, G., Stearns, C.E., (1977). Sul Tirreniano di Taranto. Datazioni su coralli con il metodo del Th230/U234. Geologica Romana 16, 231242.Google Scholar
Deperet, M.C., (1918). “Essai de corrdination chronologique de temps quaternaire”. Comptes Rendus Hebdomadaires de l'Academie des Sciences 166, 480486.Google Scholar
Dunham, R.J., (1962). Classification of carbonate rocks according to depositional texture. American Association of Petrolium Geologists Memoir 1, 108121.Google Scholar
Fleischer, L., Gafsou, R., (1998). Top Judea Group—Digital structural map of Israel. Phase 1 (Arava Valley and Galilee). The Geophysical Institute of Israel .Google Scholar
Galili, E., Eytam, Y., (1988). Young faulting in the shallow continental shelf: Evidence from northern Israel. Israel Geological Society Annual Meeting. p. 30.Google Scholar
Galili, E., Weinstein-Evron, M., (1985). Prehistory and paleoenvironments of submerged sites along the Carmel Coast of Israel. Paleorient 11, 3752.Google Scholar
Galili, E., Weinstein-Evron, M., Ronen, A., (1988). Holocene sea level changes based on submerged archaeological sites off the Northern Carmel Coast in Israel. Quaternary Research 29, 3642.CrossRefGoogle Scholar
Gignoux, M., (1955). Stratigraphic Geology. Freeman, San Francisco.Google Scholar
Gvirtzman, G., (1970). The Saqiye Group (Late Eocene to Early Pleistocene) in the Coastal Plain and the Hashephela regions. Geological Survey of Israel Report D/5/67.Google Scholar
Gvirtzman, G., (1994). Fluctuations of sea level during the past 400,000 years: The record of Sinai, Egypt (northern Red Sea). Coral Reefs 13, 203214.Google Scholar
Gvirtzman, G., Shachnai, E., Bakler, N., Illani, S., (1984). Stratigraphy of the Kurkar group (Quaternary) of the coastal plain of Israel. Geological Survey of Israel. Current Research 7082.Google Scholar
Gvirtzman, G., Martinotti, G.M., Moshkovitz, S., (1997). Stratigraphy of the Plio-Pleistocene sequence of the Mediterranean coastal belt of Israel and its implications for the evolution of the Nile cone. The Pleistocene Boundary and the Beginning of the Quaternary. Cambridge Univ. PressWorld and Regional Geology, New York.p. 156168.Google Scholar
Gvirtzman, G., Netser, M., Katzav, F. Last-Glacial to Holocene kurkar ridges, hamra soils and dune fields in the coastal belt of central Israel. Israel Journal of Earth Science .Google Scholar
Hearty, P.J., (1986). An Inventory of Last Interglacial (sensu lato) age deposits from the Mediterranean Basin: A study of Isoleucine Epimerization and U series dating. Annals of Geomorphology 62, 5170.Google Scholar
Hearty, P.J., Bonfiglio, L., Violanti, D., Szabo, B.J., (1986). Age of late Quaternary marine deposites of southern Italy determined by aminostratigraphy, faunal correlation, and uranium-series dating. Riv. It. Paleont. Strat. 92, 149164.Google Scholar
Hearty, P.J., Miller, G.H., Stearns, C.E., Szabo, B.J., (1986). Aminostratigraphy of Quaternary shorelines in the Mediterranean basin. Geological Society of America Bulletin 97, 850858.Google Scholar
Hillaire-Marcel, C., Carro, O., Causse, C., Goy, G.L., Zazo, C., (1986). Th/U dating of Strombus bubonius-bearing marine terraces in Southern Spain. Geology 14, 613616.Google Scholar
Hoang, Chi-T., Hearty, P.J., (1989). A comparison of U-series disequilibrium dates and amino acid epimerization ratios between corals and marine molluscs of Pleistocene age. Chemical Geology 79, 317323.Google Scholar
Imbrie, J., Hays, J.D., Martinson, D.J., McIntyre, A., Mix, A.C., Morley, J.J., Pisias, N.G., Prell, W.L., Shackleton, N.J., (1984). The orbital theory of Pleistocene climate: support from a revised chronology of the marine δ18 . Berger, A.I. Milankovitch and Climate 269305.Google Scholar
Inbar, M., Sivan, D., (1984). Paleo-urban development and Late Quaternary environmental change in Akko area. Paleorient 9, 8591.Google Scholar
Issar, A., (1968). Geology of the central coastal plain of Israel. Israel Journal of Earth Science 17, 1629.Google Scholar
Issar, A., Kafri, U., (1969). The discovery of a Pleistocene mammalian fauna and artifacts at “Evron”, Western Galilee. Israel Journal of Earth Science 18, 147.Google Scholar
Issar, A., Kafri, U., (1972). Neogene and Pleistocene geology of the Western Galilee coastal plain. Geological Survey of Israel Bulletin 53, 114.Google Scholar
Kafri, U., Ecker, A., (1964). Neogene and Quaternary subsurface geology and hydrology of the Zevulun Plain. Geological Survey of Israel Bulletin 37, 113.Google Scholar
Lewy, Z., Neev, D., Prausnitz, M.W., (1986). Late Holocene tectonic movements at Akhziv, Mediterranean coastline of Northern Israel. Quaternary Research 25, 177188.Google Scholar
Matthews, R.K., (1973). Relative elevation of late Pleistocene high sea level stands: Barbados uplift rates and their implications. Quaternary Research 3, 147153.Google Scholar
Mauz, B., Buccheri, G., Zoller, L., Greco, A., (1997). Middle to Upper Pleistocene morphostructural evolution of NW-coast of Sicily: thermoluminescence dating and paleontological-structural evaluation of littoral deposites. Palaeogeography, Palaeoclimatology, Palaeoecology 128, 269285.Google Scholar
Michelson, H., (1970). The Geology of the Carmel Coast. Tahal Report 025/70 .Google Scholar
Poole, A.J., Shimmield, G.B., Robertson, A.H.F., (1990). Late Quaternary uplift of the Troodos ophiolites, Cyprus: Uranium-series dating of Pleistocene coral. Geology 18, 894897.Google Scholar
Prausnitz, M.W., (1969). The sequence of Early To Middle Paleolithic flint industries along the Galilee Littoral. Israel Exploration Journal 19, 132136.Google Scholar
Reineck, H.-E., Singh, I.B., (1973). Depositional Sedimentary Environments. Springer-Verlag, Berlin.Google Scholar
Reiss, Z., Issar, A., (1961). Contributions to the study of the Pleistocene in the coastal Plain of Israel. Subsurface Quaternary correlations in the Tel Aviv Region. Geological Survey of Israel Bulletin 32, 1028.Google Scholar
Rohrlich, V., Wiseman, G., Komornik, A., (1993). Overconsolidated clays from the Israeli Mediterranean coast and inner shelf. Annual Meeting on the Mediterranean margin of Israel.Google Scholar
Ronen, A., (1991). The Lower Paleolithic site Evron-Quarry in Western Galilee. Israel. Sonderveroffentlichungen, Geologisches Institut der Universitat zu Koln 82, 187212.Google Scholar
Sanlaville, P., (1980). Stratigraphie et chronologie du Quaternaire marine du Levante, prehistoire du Levante. Colloques Internationaux du Center National de la recherche Scientifique 2131.Google Scholar
Sivan, D., (1981). Paleogeography of Akko Area in the Holocene Period. Haifa University, Haifa.Google Scholar
Sivan, D., (1995). Paleogeography of the Galilee Coastal Plain during the Quaternary. Hebrew University, Jerusalem.Google Scholar
Sivan, D., (1996). Paleogeography of the Galilee Coastal Plain during the Quaternary. Geological Survey of Israel Report 18/96.Google Scholar
Sivan, D., Gvirtzman, G., (1991). The Quaternary stratigraphy of the western Galilee coastal plain. Israel Geological Society Annual Meeting Akko. Field Trips Guidebook. p. 1729.Google Scholar
Sivan, D., Gvirtzman, G., Sass, E., (1992). Distinction between marine and eolian kurkar: An example from the Galilee shore. Israel Geological Society Annual Meeting. p. 143.Google Scholar
Sivan, D., Gvirtzman, G., Kaufman, A., Sass, E., (1994). The Yasaf Member: A Strombus bearing unit on the coast of Galilee representing Tyrrhenian event in the Mediterranean. Israel Geological Society Annual Meeting. p. 106.Google Scholar
Slatkine, A., Rohrlich, V., (1963). Sediments du Quaternaire de la Plaine de Haifa. Israel Journal of Earth Science 12, 159206.Google Scholar
Sneh, Y., Klein, M., (1984). Holocene sea level changes of the coast of Dor, southern Mediterranean. Science 226, 831832.Google Scholar
Soliman, S.M., (1964). Primary structures in a part of the Nile Delta sand beach. Van Straaten, L.M.J.V. Deltaic and Shallow Marine Deposites 379387.CrossRefGoogle Scholar
Tchernov, E., Horowitz, L., Ronen, A., Lister, A., (1994). The faunal remains from Evron Quarry in relation to other Lower Paleolithic hominid sites in the Southern Levant. Quaternary Research 42, 328339.Google Scholar
Ulzega, A., Hearty, P.J., (1986). Geomorphology, stratigraphy, and geochronology of Late Quaternary marine depodites in Sardinia. Annals of Geomorphology 62, 119130.Google Scholar
Ziberman, E., (1991). Geological Survey of Israel . Report 45/90.Google Scholar