Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-28T03:53:36.488Z Has data issue: false hasContentIssue false

Controls on the Radiocarbon Reservoir Ages in the Modern Dead Sea Drainage System and in the Last Glacial Lake Lisan

Published online by Cambridge University Press:  18 July 2016

Reuven Belmaker*
Affiliation:
Institute of Earth Science, Hebrew University, Jerusalem, Israel 91904
Mordechai Stein
Affiliation:
Geological Survey of Israel, Jerusalem, Israel 95501
Yoseph Yechieli
Affiliation:
Geological Survey of Israel, Jerusalem, Israel 95501
Boaz Lazar
Affiliation:
Institute of Earth Science, Hebrew University, Jerusalem, Israel 91904
*
Corresponding author. Email: ruvke@pob.huji.ac.il
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Carbon isotopic and chemical compositions of freshwaters feeding the Dead Sea and the Sea of Galilee (i.e. perennial streams and floods along their stream profiles) were used to constrain the factors that dictate the reservoir ages (RA) of these lakes and the last glacial Lake Lisan. Runoff waters are characterized by high Ca2+, Mg2+, alkalinity, and radiocarbon contents (67–108 pMC), suggesting a major role for 14C atmospheric exchange reactions (carbonate rock dissolution alone will result in lower pMC values). These exchange processes were corroborated by dissolved inorganic carbon (DIC) and δ13C trends throughout the flood profile. During the evolution from rain to incipient runoff, the 14CDIC of the water increases and is accompanied by a DIC increase and δ13CDIC decrease, suggesting an addition of soil CO2, which is characterized by light δ13C and high 14C content. When incipient runoffs evolve to floods, the opposite trends are observed.

It appears that the Sea of Galilee, the Dead Sea, and its last glacial precursor, Lake Lisan, maintained uniform but specific RAs of 0.8 ± 0.1, 2.3 ± 0.1, and 1.6 ± 0.3 kyr, respectively. However, applying the 14C contents of modern Dead Sea water sources to the water mass balance of Lake Lisan reveals that the RA of Lake Lisan is higher than that predicted by the mass balance. This discrepancy may reflect enhanced dissolution of carbonatic dust, changes in the amount of 14C exchanged in Judean Desert floods, or variations in the contribution of brine and saline springs. Furthermore, the small fluctuations in the Lisan RA (1.6 ± 0.3 kyr) may reflect small, short-term changes in the relative contributions of these sources.

Type
Articles
Copyright
Copyright © 2007 by the Arizona Board of Regents on behalf of the University of Arizona 

References

Barkan, E, Luz, B, Lazar, B. 2001. Dynamics of the carbon dioxide system in the Dead Sea. Geochimica et Cosmochimica Acta 65(3):355–68.Google Scholar
Bartov, Y, Stein, M, Enzel, Y, Agnon, A, Reches, Z. 2002. Lake levels and sequence stratigraphy of Lake Lisan, the late Pleistocene precursor of the Dead Sea. Quaternary Research 57(1):921.CrossRefGoogle Scholar
Bartov, Y, Goldstein, SL, Stein, M, Enzel, Y. 2003. Catastrophic arid episodes in the eastern Mediterranean linked with the North Atlantic Heinrich events. Geology 31(5):439–42.Google Scholar
Bentor, YK. 1961. Some geochemical aspects of the Dead Sea and the question of its age. Geochimica et Cosmochimica Acta 25(4):239–60.CrossRefGoogle Scholar
Bookman, R, Lazar, B, Stein, M, Burr, GS. 2007. Radiocarbon dating of primary aragonite by sequential extraction of CO2 . The Holocene 17(1):131–7.CrossRefGoogle Scholar
Broecker, WS, Walton, A. 1959. The geochemistry of 14C in fresh-water systems. Geochimica et Cosmochimica Acta 16(1–3):1538.Google Scholar
Carmi, I, Stiller, M, Kaufman, A. 1985. The effect of atmospheric 14C variations on the 14C levels in the Jordan River system. Radiocarbon 27(2B):305–13.Google Scholar
Frumkin, A, Stein, M. 2004. The Sahara-East Mediterranean dust and climate connection revealed by strontium and uranium isotopes in a Jerusalem speleothem. Earth and Planetary Science Letters 217(3–4):451–64.CrossRefGoogle Scholar
Ganor, E, Foner, HA. 1996. The mineralogical and chemical properties and the behaviour of Aeolian Saharan dust over Israel. In: Guerzoni, S, Chester, R, editors. The Impact of Desert Dust Across the Mediterranean. Dordrecht: Kluwer Academic. p 163–72.Google Scholar
Ganor, E, Mamane, Y. 1982. Transport of Saharan dust across the eastern Mediterranean. Atmospheric Environment 16(3):581–7.Google Scholar
Garfunkel, Z. 1997. The history and formation of the Dead Sea basin. In: Niemi, TM, Ben-Avraham, Z, Gat, JR, editors. The Dead Sea: The Lake and Its Setting. Oxford: Oxford University Press. p 3656.Google Scholar
Hazan, N, Stein, M, Agnon, A, Marco, S, Nadel, D, Negendank, JFW, Schwab, MJ, Neev, D. 2005. The late Quaternary limnological history of Lake Kinneret (Sea of Galilee), Israel. Quaternary Research 63(1):6077.CrossRefGoogle Scholar
Holland, DH. 1979. The Chemistry of the Atmosphere and Oceans. New York: John Wiley & Sons. 369 p.Google Scholar
Lev, L, Boaretto, E, Heller, J, Marco, S, Stein, M. 2007. The feasibility of using Melanopsis shells as radiocarbon chronometers, Lake Kinneret, Israel. Radiocarbon , these proceedings.CrossRefGoogle Scholar
Levin, I, Kromer, B. 1997. Twenty years of atmospheric 14CO2 observations at Schauinsland station, Germany. Radiocarbon 39(2):205–18.Google Scholar
Lewenberg, O. 2005. The hydrogeology and geochemistry of groundwater in the alluvial fan of Wadi Arugot, En Gedi reservation [MSc thesis]. Jerusalem: Hebrew University of Jerusalem. In Hebrew.Google Scholar
Machlus, M. 1996. Geochemical parameters in the Lisan Formation aragonite—proxies for paleolimnology of Lake Lisan and climatic history of the Dead Sea region [MSc thesis]. Jerusalem: Hebrew University of Jerusalem. In Hebrew.Google Scholar
Neaman, A, Singer, A, Stahr, K. 1999. Clay mineralogy as affecting disaggregation in some palygorskite containing soils of the Jordan and Bet-She'an valleys. Australian Journal of Soil Research 37(5):913–28.Google Scholar
Neev, D, Emery, KO. 1967. The Dead Sea: Depositional Processes and Environments of Evaporates. Jerusalem: Geological Survey of Israel Bulletin 41. 147 p.Google Scholar
Prasad, S, Vos, H, Negendank, JFW, Waldmann, N, Goldstein, SL, Stein, M. 2004. Evidence from Lake Lisan of solar influence on decadal- to centennial-scale climate variability during marine oxygen isotope stage 2. Geology 32(7):581–4.Google Scholar
Stein, M, Starinsky, A, Katz, A, Goldstein, SL, Machlus, M, Schramm, A. 1997. Strontium isotopic, chemical, and sedimentological evidence for the evolution of Lake Lisan and the Dead Sea. Geochimica et Cosmochimica Acta 61(18):3975–92.CrossRefGoogle Scholar
Stein, M, Migowski, C, Bookman, R, Lazar, B. 2004. Temporal changes in radiocarbon reservoir age in the Dead Sea-Lake Lisan system. Radiocarbon 46(2):649–55.Google Scholar
Talma, AS, Vogel, JC, Stiller, M. 1997. The radiocarbon content of the Dead Sea. In: Niemi, TM, Ben-Avraham, Z, Gat, JR, editors. The Dead Sea: The Lake and Its Setting. Oxford: Oxford University Press. p 193–8.Google Scholar
Weinstein, YS. 1998. Mechanisms of generation of intracontinental alkali-basalt in northern Israel [PhD dissertation]. Jerusalem: Hebrew University of Jerusalem.Google Scholar
Yechieli, Y, Ronen, D, Kaufman, A. 1996. The source and age of groundwater brines in the Dead Sea area, as deduced from 36Cl and 14C. Geochimica et Cosmochimica Acta 60(11):1909–16.Google Scholar