A new 36Cl hydrological model and 36Cl systematics in the Jordan River/Dead Sea system

M. Paul; A. Kaufman; M. Magaritz; D. Fink; W. Henning; R. Kaim; W. Kutschera; O. Meirav

doi:10.1038/321511a0

A new ³⁶Cl hydrological model and ³⁶Cl systematics in the Jordan River/Dead Sea system

M. Paul^*
, A. Kaufman
, M. Magaritz
, D. Fink
, W. Henning
, R. Kaim
, W. Kutschera
, O. Meirav

^*Corresponding author for this work

Racah Institute of Physics

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

The recent breakthrough in our ability to detect the radioactive isotope ³⁶Cl (half-life T_1/2 = 301,000 yr) at natural levels by accelerator mass spectrometry¹ allows the processes of salination of water systems to be studied in a new way by distinguishing the chloride content originating in young rainwaters and their subsequent evaporation from that generated by the leaching of ancient rocks. Results for the Jordan River/Dead Sea system show that the amount of chloride leached from rocks ranges from ∼70% in source springs to >90% in water bodies downstream. Furthermore, the amount of water left after evaporation decreases from ∼50% in the source springs to 20% in the intermediate Lake Kinneret. In the terminal Dead Sea, 99% of the stable chloride originates from ancient rocks and evaporite formations while ∼80% of its ³⁶Cl content is of meteoric origin. Using ³⁶Cl measurements, we estimate the accumulation time of the Dead Sea salt to be 19,000-25,000 yr.

Original language	English
Pages (from-to)	511-515
Number of pages	5
Journal	Nature
Volume	321
Issue number	6069
DOIs	https://doi.org/10.1038/321511a0
State	Published - 1986

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title = "A new 36Cl hydrological model and 36Cl systematics in the Jordan River/Dead Sea system",

abstract = "The recent breakthrough in our ability to detect the radioactive isotope 36Cl (half-life T1/2 = 301,000 yr) at natural levels by accelerator mass spectrometry1 allows the processes of salination of water systems to be studied in a new way by distinguishing the chloride content originating in young rainwaters and their subsequent evaporation from that generated by the leaching of ancient rocks. Results for the Jordan River/Dead Sea system show that the amount of chloride leached from rocks ranges from ∼70\% in source springs to >90\% in water bodies downstream. Furthermore, the amount of water left after evaporation decreases from ∼50\% in the source springs to 20\% in the intermediate Lake Kinneret. In the terminal Dead Sea, 99\% of the stable chloride originates from ancient rocks and evaporite formations while ∼80\% of its 36Cl content is of meteoric origin. Using 36Cl measurements, we estimate the accumulation time of the Dead Sea salt to be 19,000-25,000 yr.",

author = "M. Paul and A. Kaufman and M. Magaritz and D. Fink and W. Henning and R. Kaim and W. Kutschera and O. Meirav",

year = "1986",

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T1 - A new 36Cl hydrological model and 36Cl systematics in the Jordan River/Dead Sea system

AU - Paul, M.

AU - Kaufman, A.

AU - Magaritz, M.

AU - Fink, D.

AU - Henning, W.

AU - Kaim, R.

AU - Kutschera, W.

AU - Meirav, O.

PY - 1986

Y1 - 1986

N2 - The recent breakthrough in our ability to detect the radioactive isotope 36Cl (half-life T1/2 = 301,000 yr) at natural levels by accelerator mass spectrometry1 allows the processes of salination of water systems to be studied in a new way by distinguishing the chloride content originating in young rainwaters and their subsequent evaporation from that generated by the leaching of ancient rocks. Results for the Jordan River/Dead Sea system show that the amount of chloride leached from rocks ranges from ∼70% in source springs to >90% in water bodies downstream. Furthermore, the amount of water left after evaporation decreases from ∼50% in the source springs to 20% in the intermediate Lake Kinneret. In the terminal Dead Sea, 99% of the stable chloride originates from ancient rocks and evaporite formations while ∼80% of its 36Cl content is of meteoric origin. Using 36Cl measurements, we estimate the accumulation time of the Dead Sea salt to be 19,000-25,000 yr.

AB - The recent breakthrough in our ability to detect the radioactive isotope 36Cl (half-life T1/2 = 301,000 yr) at natural levels by accelerator mass spectrometry1 allows the processes of salination of water systems to be studied in a new way by distinguishing the chloride content originating in young rainwaters and their subsequent evaporation from that generated by the leaching of ancient rocks. Results for the Jordan River/Dead Sea system show that the amount of chloride leached from rocks ranges from ∼70% in source springs to >90% in water bodies downstream. Furthermore, the amount of water left after evaporation decreases from ∼50% in the source springs to 20% in the intermediate Lake Kinneret. In the terminal Dead Sea, 99% of the stable chloride originates from ancient rocks and evaporite formations while ∼80% of its 36Cl content is of meteoric origin. Using 36Cl measurements, we estimate the accumulation time of the Dead Sea salt to be 19,000-25,000 yr.

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A new ³⁶Cl hydrological model and ³⁶Cl systematics in the Jordan River/Dead Sea system

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