The Dead Sea is an extremely dynamic hydrologic system, where the base level is currently declining at a rate of ∼1 m/yr. The groundwater level follows this drop within a relatively short time (a few days in the case of the extensive floods in the winter of 1991–1992). The fresh-saline water interface is very shallow, compared to that of the ocean, due to the large density difference between the fresh and saline water bodies. The interface was found to be steeper near the marginal faults, tracked in a time domain electromagnetic geophysical survey, due to the relatively low horizontal hydraulic conductivity at the fault zone. SUTRA code simulations support this result. Near the shoreline of the Dead Sea, a new coastal area is exposed, whereby the main processes are flushing of most of the section and evaporation and precipitation of salts near the surface. The effect of flushing is seen in several in situ profiles that show much lower concentrations than the original Dead Sea brine, which existed only a few decades ago. Preliminary simulations on a larger scale imply that the Dead Sea water level drop will influence groundwater levels at least several kilometers from the shoreline, increasing the hydraulic gradient and thus also the discharge to the Dead Sea.

Over the past several years, the coastal area around the declining Dead Sea has undergone a catastrophic collapse. One of the major expressions of this process is the sudden appearance of hundreds of collapse sinkholes, causing a severe threat to the future of this region. Here we review results and inferences obtained from a multidisciplinary research conducted since 1999. Observations were obtained by geological mapping, aerial photographs, drilling, groundwater geochemistry, seismic refraction and reflection, and satellite radar interferometry. The suggested model for the formation of the Dead Sea sinkholes is based on the following observations: (1) presence of a thick salt layer (or layers) at depths between 20 and 50 m (depth of layer top), and sandwiched between aquiclude layers of clay and silt; (2) identification of cavities within the salt layer in sinkhole sites; (3) presence of water undersaturated with respect to halite in aquifers confined beneath the salt layer; (4) composition of the groundwater in the salt layer that indicates salt dissolution; (5) association between sinkhole sites and land subsidence; and (6) formation of sinkholes along and above buried faults. These observations combine to suggest that the primary cause of sinkhole formation is dissolution of the salt layer by undersaturated groundwater. The interface between the Dead Sea brine and this groundwater migrated eastward due to the Dead Sea decline. Undersaturated water accessed the salt layer via faults that cut through the soft aquiclude layers. The opening of these conduit-faults is likely due to differential compaction of the aquiclude layers, explaining the correlation between the land subsidence and sinkhole sites. It appears that the decline of the Dead Sea level affects the formation of sinkholes in three ways: (1) opening the way to eastward migration of the fresh-saline water interface and thus to undersaturated groundwater, (2) generating differential compaction of fine-grained sediments, and (3) destabilization of underground cavities, which catalyzes their collapse.