Premium
Combined time‐series resistivity and geochemical tracer techniques to examine submarine groundwater discharge at Dor Beach, Israel
Author(s) -
Swarzenski P. W.,
Burnett W. C.,
Greenwood W. J.,
Herut B.,
Peterson R.,
Dimova N.,
Shalem Y.,
Yechieli Y.,
Weinstein Y.
Publication year - 2006
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/2006gl028282
Subject(s) - submarine groundwater discharge , hydrogeology , geology , groundwater , shore , groundwater discharge , hydrology (agriculture) , seawater , electrical resistivity tomography , oceanography , groundwater flow , electrical resistivity and conductivity , aquifer , geotechnical engineering , electrical engineering , engineering
A high‐resolution, stationary geophysical and geochemical survey was conducted at Dor Beach, Israel, to examine the shallow coastal hydrogeology and its control on the exchange of submarine groundwater with the shallow Mediterranean Sea. Time‐series resistivity profiles using a new 56 electrode (112‐m long) marine cable produced detailed profiles of the fresh water/salt water interface and the subtle response of this interface to tidal excursions and other forcing factors. Such information, when ground‐truthed with representative pore water salinities and formation resistivity values, can provide unique information of the extent and rates of submarine groundwater discharge (SGD). Time‐series 222 Rn measurements of the adjacent coastal water column complemented these geophysical techniques and were modeled to yield integrated advective flow rates across the sediment/water interface, which at Dor Beach ranged from about 0 to 30 cm day −1 (mean = 7.1 cm d −1 ), depending on the tidal range. Such results suggest that the underlying hydrogeologic framework at Dor is favorable for substantial SGD. Extrapolating these SGD estimates across a 100‐m wide coastal zone implies that the Rn‐derived SGD rate would equal ∼7.1 m 3 d −1 per m of shoreline, and that the source of this discharging groundwater is a complex mixture of fresh groundwater derived from the upland Kurkar deposits, as well as locally recycled seawater.