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Quaternary rise of the Sedom diapir, Dead Sea basin
Mount Sedom is the surface expression of a salt diapir that has emerged since the Pleistocene in the southwestern part of
the Dead Sea basin. Milestones in the uplift history of the Sedom salt diapir since its inception were deduced from angular
and erosional unconformities, thickness variations, caprock formation, chemistry and isotope composition of lacustrine aragonite,
cave morphology, precise leveling, and satellite geodesy. Thickness variations of the overburden observed in transverse seismic
lines suggest that significant growth of the Sedom diapir may have initiated only after this thickness exceeded ∼2400 m in
the Late Pliocene. The formation of the caprock signifies the arrival of the Sedom diapir from depth to the dissolution level
between 300,000–100,000 yr B.P. During this period and later, angular and erosional unconformities in the upper part of the
overburden near Mount Sedom are attributed to the piercing diapir. Rapid solution of rock salt from parts of Mount Sedom inundated
by Lake Lisan after ca. 40,000 yr B.P. is inferred from Na/Ca ratios in aragonite and their relation to δ 13 C. On the mountain itself, the older parts (70,000–43,000 yr B.P.) of the lacustrine Lisan Formation are missing. The top
of the preserved sediments is covered by alluvial sediments that must have been deposited when the elevation of Mount Sedom
was not higher than 265 m below sea level (mbsl) at ca. 14,000 yr B.P. The present elevation of these sediments at 190 mbsl
indicates an average uplift rate of ∼5 mm/yr over the past 14,000 yr. Similar uplift rates of 6–9 mm/yr are inferred for the
Holocene from displacement of the “salt mirror” and hanging passages of caves. The present uplift rate, calculated from precise
leveling and interferometric synthetic aperture radar (InSAR), is similar to the average Holocene rate. Based on the gathered
data, we reconstruct the topographic rise of Sedom diapir and its relation to lake level variations during the late Pleistocene
and Holocene