Imaging and quantifying salt-tracer transport in a riparian groundwater system by means of 3D ERT monitoring

Lancaster Environment Centre

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https://doi.org/10.1190/GEO2012-0046.1
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Keywords

HETEROGENEOUS AQUIFER, CONDUCTIVITY, ELECTRICAL-RESISTIVITY TOMOGRAPHY, FLOW MODEL, SOLUTE TRANSPORT, TIME-SERIES, 3-DIMENSIONAL GEORADAR, LOSING STREAM, VADOSE ZONE, BANK FILTRATION

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Imaging and quantifying salt-tracer transport in a riparian groundwater system by means of 3D ERT monitoring. / Doetsch, Joseph; Linde, Niklas; Vogt, Tobias et al.
In: Geophysics, Vol. 77, No. 5, 2012, p. B207-B218.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Author

Doetsch, Joseph ; Linde, Niklas ; Vogt, Tobias et al. / Imaging and quantifying salt-tracer transport in a riparian groundwater system by means of 3D ERT monitoring. In: Geophysics. 2012 ; Vol. 77, No. 5. pp. B207-B218.

Bibtex

@article{62dd6db28d684a78b82e991bf92d568d,

title = "Imaging and quantifying salt-tracer transport in a riparian groundwater system by means of 3D ERT monitoring",

abstract = "Determining groundwater flow paths of infiltrated river water is necessary for studying biochemical processes in the riparian zone, but their characterization is complicated by strong temporal and spatial heterogeneity. We investigated to what extent repeat 3D surface electrical resistance tomography (ERT) can be used to monitor transport of a salt-tracer plume under close to natural gradient conditions. The aim is to estimate groundwater flow velocities and pathways at a site located within a riparian groundwater system adjacent to the perialpine Thur River in northeastern Switzerland. Our ERT time-lapse images provide constraints on the plume's shape, flow direction, and velocity. These images allow the movement of the plume to be followed for 35 m. Although the hydraulic gradient is only 1.43 parts per thousand, the ERT time-lapse images demonstrate that the plume's center of mass and its front propagate with velocities of 2x10(-4) m/s and 5x10(-4) m/s, respectively. These velocities are compatible with groundwater resistivity monitoring data in two observation wells 5 m from the injection well. Five additional sensors in the 5-30 m distance range did not detect the plume. Comparison of the ERT time-lapse images with a groundwater transport model and time-lapse inversions of synthetic ERT data indicate that the movement of the plume can be described for the first 6 h after injection by a uniform transport model. Subsurface heterogeneity causes a change of the plume's direction and velocity at later times. Our results demonstrate the effectiveness of using time-lapse 3D surface ERT to monitor flow pathways in a challenging perialpine environment over larger scales than is practically possible with crosshole 3D ERT.",

keywords = "HETEROGENEOUS AQUIFER, CONDUCTIVITY, ELECTRICAL-RESISTIVITY TOMOGRAPHY, FLOW MODEL, SOLUTE TRANSPORT, TIME-SERIES, 3-DIMENSIONAL GEORADAR, LOSING STREAM, VADOSE ZONE, BANK FILTRATION",

author = "Joseph Doetsch and Niklas Linde and Tobias Vogt and Andrew Binley and Green, {Alan G.}",

year = "2012",

doi = "10.1190/GEO2012-0046.1",

language = "English",

volume = "77",

pages = "B207--B218",

journal = "Geophysics",

issn = "0016-8033",

publisher = "Society Of Exploration Geophysicists",

number = "5",

}

RIS

TY - JOUR

T1 - Imaging and quantifying salt-tracer transport in a riparian groundwater system by means of 3D ERT monitoring

AU - Doetsch, Joseph

AU - Linde, Niklas

AU - Vogt, Tobias

AU - Binley, Andrew

AU - Green, Alan G.

PY - 2012

Y1 - 2012

N2 - Determining groundwater flow paths of infiltrated river water is necessary for studying biochemical processes in the riparian zone, but their characterization is complicated by strong temporal and spatial heterogeneity. We investigated to what extent repeat 3D surface electrical resistance tomography (ERT) can be used to monitor transport of a salt-tracer plume under close to natural gradient conditions. The aim is to estimate groundwater flow velocities and pathways at a site located within a riparian groundwater system adjacent to the perialpine Thur River in northeastern Switzerland. Our ERT time-lapse images provide constraints on the plume's shape, flow direction, and velocity. These images allow the movement of the plume to be followed for 35 m. Although the hydraulic gradient is only 1.43 parts per thousand, the ERT time-lapse images demonstrate that the plume's center of mass and its front propagate with velocities of 2x10(-4) m/s and 5x10(-4) m/s, respectively. These velocities are compatible with groundwater resistivity monitoring data in two observation wells 5 m from the injection well. Five additional sensors in the 5-30 m distance range did not detect the plume. Comparison of the ERT time-lapse images with a groundwater transport model and time-lapse inversions of synthetic ERT data indicate that the movement of the plume can be described for the first 6 h after injection by a uniform transport model. Subsurface heterogeneity causes a change of the plume's direction and velocity at later times. Our results demonstrate the effectiveness of using time-lapse 3D surface ERT to monitor flow pathways in a challenging perialpine environment over larger scales than is practically possible with crosshole 3D ERT.

AB - Determining groundwater flow paths of infiltrated river water is necessary for studying biochemical processes in the riparian zone, but their characterization is complicated by strong temporal and spatial heterogeneity. We investigated to what extent repeat 3D surface electrical resistance tomography (ERT) can be used to monitor transport of a salt-tracer plume under close to natural gradient conditions. The aim is to estimate groundwater flow velocities and pathways at a site located within a riparian groundwater system adjacent to the perialpine Thur River in northeastern Switzerland. Our ERT time-lapse images provide constraints on the plume's shape, flow direction, and velocity. These images allow the movement of the plume to be followed for 35 m. Although the hydraulic gradient is only 1.43 parts per thousand, the ERT time-lapse images demonstrate that the plume's center of mass and its front propagate with velocities of 2x10(-4) m/s and 5x10(-4) m/s, respectively. These velocities are compatible with groundwater resistivity monitoring data in two observation wells 5 m from the injection well. Five additional sensors in the 5-30 m distance range did not detect the plume. Comparison of the ERT time-lapse images with a groundwater transport model and time-lapse inversions of synthetic ERT data indicate that the movement of the plume can be described for the first 6 h after injection by a uniform transport model. Subsurface heterogeneity causes a change of the plume's direction and velocity at later times. Our results demonstrate the effectiveness of using time-lapse 3D surface ERT to monitor flow pathways in a challenging perialpine environment over larger scales than is practically possible with crosshole 3D ERT.

KW - HETEROGENEOUS AQUIFER

KW - CONDUCTIVITY

KW - ELECTRICAL-RESISTIVITY TOMOGRAPHY

KW - FLOW MODEL

KW - SOLUTE TRANSPORT

KW - TIME-SERIES

KW - 3-DIMENSIONAL GEORADAR

KW - LOSING STREAM

KW - VADOSE ZONE

KW - BANK FILTRATION

U2 - 10.1190/GEO2012-0046.1

DO - 10.1190/GEO2012-0046.1

M3 - Journal article

VL - 77

SP - B207-B218

JO - Geophysics

JF - Geophysics

SN - 0016-8033

IS - 5

ER -

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