Redistribution of contaminants by a fluctuating water table in a micro-porous, double-porosity aquifer: field observations and model simulations
Redistribution of contaminants by a fluctuating water table in a micro-porous, double-porosity aquifer: field observations and model simulations
Large seasonal fluctuations of the water table are characteristic of aquifers with a low specific yield, including those fractured, double-porosity aquifers that have significant matrix porosity containing virtually immobile porewater, such as the Chalk of northern Europe. Where these aquifers are contaminated, a strong relationship between water table elevation and contaminant concentration in groundwater is commonly observed, of significance to the assessment, monitoring, and remediation of contaminated groundwater. To examine the processes governing contaminant redistribution by a fluctuating water table within the ‘seasonally unsaturated zone’, or SUZ, profiles of porewater solute concentrations have been established at a contaminated site in southern England. These profiles document the contaminant distribution in porewater of the Chalk matrix over the SUZ at a greater level of detail than recorded previously. A novel double-porosity solute transport code has been developed to simulate the evolution of the SUZ matrix porewater contaminant profiles, given a fluctuating water table, when the groundwater is initially contaminated and the SUZ is initially free of contamination. The model is simply characterised by: the matrix-fracture porosity ratio, the matrix block geometry, and a characteristic diffusion time. De-saturation and re-saturation of fractures is handled by a new approximation method. Contaminant accumulates in the upper levels of the SUZ, where it is less accessible to mobile groundwater, and acts as a persistent secondary source of contamination once the original source of contamination has been removed or has become depleted. The ‘SUZ process’ first attenuates the progress of contaminants in groundwater, and subsequently controls the slow release of contamination back to the mobile groundwater, thus prolonging the duration of groundwater contamination by many years. The SUZ process should operate in any fractured, micro-porous lithology e.g. fractured clays and mudstones, making this approach widely applicable.
unsaturated, double-porosity, diffusion, contaminants, chalk, modelling
27-52
Fretwel, B.A.
74fb23df-0b9e-4397-aa42-cc774769effa
Burgess, W.G.
2419c10e-cf7b-458d-9820-ec9e619e73eb
Barker, J.A.
33bf9dec-cc9b-451c-8192-46099e316b6d
Jefferies, N.L.
7dca291c-9c0d-4a44-8f6c-6b9e14121981
8 June 2005
Fretwel, B.A.
74fb23df-0b9e-4397-aa42-cc774769effa
Burgess, W.G.
2419c10e-cf7b-458d-9820-ec9e619e73eb
Barker, J.A.
33bf9dec-cc9b-451c-8192-46099e316b6d
Jefferies, N.L.
7dca291c-9c0d-4a44-8f6c-6b9e14121981
Fretwel, B.A., Burgess, W.G., Barker, J.A. and Jefferies, N.L.
(2005)
Redistribution of contaminants by a fluctuating water table in a micro-porous, double-porosity aquifer: field observations and model simulations.
Journal of Contaminant Hydrology, 78 (1-2), .
(doi:10.1016/j.jconhyd.2005.02.004).
Abstract
Large seasonal fluctuations of the water table are characteristic of aquifers with a low specific yield, including those fractured, double-porosity aquifers that have significant matrix porosity containing virtually immobile porewater, such as the Chalk of northern Europe. Where these aquifers are contaminated, a strong relationship between water table elevation and contaminant concentration in groundwater is commonly observed, of significance to the assessment, monitoring, and remediation of contaminated groundwater. To examine the processes governing contaminant redistribution by a fluctuating water table within the ‘seasonally unsaturated zone’, or SUZ, profiles of porewater solute concentrations have been established at a contaminated site in southern England. These profiles document the contaminant distribution in porewater of the Chalk matrix over the SUZ at a greater level of detail than recorded previously. A novel double-porosity solute transport code has been developed to simulate the evolution of the SUZ matrix porewater contaminant profiles, given a fluctuating water table, when the groundwater is initially contaminated and the SUZ is initially free of contamination. The model is simply characterised by: the matrix-fracture porosity ratio, the matrix block geometry, and a characteristic diffusion time. De-saturation and re-saturation of fractures is handled by a new approximation method. Contaminant accumulates in the upper levels of the SUZ, where it is less accessible to mobile groundwater, and acts as a persistent secondary source of contamination once the original source of contamination has been removed or has become depleted. The ‘SUZ process’ first attenuates the progress of contaminants in groundwater, and subsequently controls the slow release of contamination back to the mobile groundwater, thus prolonging the duration of groundwater contamination by many years. The SUZ process should operate in any fractured, micro-porous lithology e.g. fractured clays and mudstones, making this approach widely applicable.
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Published date: 8 June 2005
Keywords:
unsaturated, double-porosity, diffusion, contaminants, chalk, modelling
Identifiers
Local EPrints ID: 53135
URI: http://eprints.soton.ac.uk/id/eprint/53135
ISSN: 0169-7722
PURE UUID: 4e5cae1a-a957-40c6-9d8f-14b5ad0d941a
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Date deposited: 22 Jul 2008
Last modified: 15 Mar 2024 10:40
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Author:
B.A. Fretwel
Author:
W.G. Burgess
Author:
N.L. Jefferies
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