Mapping of the hyporheic zone around a tidal creek using a combination of borehole logging, borehole electrical tomography and cross-creek electrical imaging, New South Wales, Australia

A combination of electrical imaging carried out across a tidal creek and borehole electrical tomography between strings of electrodes installed in bores adjacent to the creek is used to establish the shape of the hyporheic zone beneath a tidal creek in a sand aquifer. The interpretations provided by...

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Veröffentlicht in:	Hydrogeology journal 2003-06, Vol.11 (3), p.368-377
Hauptverfasser:	Acworth, R I, Dasey, G R
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Sprache:	eng
Schlagworte:	Aquifers Boreholes Chemical analysis Creeks Creeks & streams Fluid dynamics Fluid flow Fluids Geophysics Groundwater Groundwater discharge Groundwater recharge Hyporheic zones Imaging Piezometers Piezometric head Sand Sand aquifers Seawater Tomography Water analysis
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creator	Acworth, R I Dasey, G R
description	A combination of electrical imaging carried out across a tidal creek and borehole electrical tomography between strings of electrodes installed in bores adjacent to the creek is used to establish the shape of the hyporheic zone beneath a tidal creek in a sand aquifer. The interpretations provided by the data inversions are checked against fluid electrical conductivity (EC) samples collected from bundled piezometers installed in the creek banks and from bulk EC measurements made using induction logs in bores on the creek banks. Extensive seepage into the base of the creek is identified from the electrical image and verified by independent measurements of hydraulic head and fluid EC. The Effective Medium Theory is used to derive values of fluid EC from bulk resistivity measurements obtained from the inversion process. The data show an extensive zone of mixing between seawater and rainwater recharge into the aquifer, with the shape of the hyporheic zone strongly influenced by regional groundwater discharge and the presence of a thin layer of cemented sands at a depth of 10 m. The combined interpretation demonstrates the importance of borehole control in the interpretation of electrical images measured from the surface over complex EC distributions.
doi_str_mv	10.1007/s10040-003-0258-4
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subjects	Aquifers Boreholes Chemical analysis Creeks Creeks & streams Fluid dynamics Fluid flow Fluids Geophysics Groundwater Groundwater discharge Groundwater recharge Hyporheic zones Imaging Piezometers Piezometric head Sand Sand aquifers Seawater Tomography Water analysis
title	Mapping of the hyporheic zone around a tidal creek using a combination of borehole logging, borehole electrical tomography and cross-creek electrical imaging, New South Wales, Australia
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