Modeling field-scale cosolvent flooding for DNAPL source zone remediation

A three-dimensional, compositional, multiphase flow simulator was used to model a field-scale test of DNAPL removal by cosolvent flooding. The DNAPL at this site was tetrachloroethylene (PCE), and the flooding solution was an ethanol/water mixture, with up to 95% ethanol. The numerical model, UTCHEM...

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Bibliographic Details
Published in:Journal of contaminant hydrology 2008-02, Vol.96 (1), p.1-16
Main Authors: Liang, Hailian, Falta, Ronald W.
Format: Article
Language:English
Subjects:
Alcohol flooding
Calibration
Computer Simulation
Cosolvent flooding
cosolvents
Disasters
DNAPL remediation
Earth sciences
Earth, ocean, space
ethanol
Exact sciences and technology
groundwater contamination
Hydrogeology
hydrologic models
Hydrology. Hydrogeology
Kinetics
mass transfer
mathematical models
Models, Chemical
Multiphase flow
Numerical modeling
remediation
simulation models
solvents
Solvents - chemistry
tetrachloroethylene
Tetrachloroethylene - chemistry
UTCHEM
UTCHEM model
water
Water - chemistry
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Summary:A three-dimensional, compositional, multiphase flow simulator was used to model a field-scale test of DNAPL removal by cosolvent flooding. The DNAPL at this site was tetrachloroethylene (PCE), and the flooding solution was an ethanol/water mixture, with up to 95% ethanol. The numerical model, UTCHEM accounts for the equilibrium phase behavior and multiphase flow of a ternary ethanol–PCE–water system. Simulations of enhanced cosolvent flooding using a kinetic interphase mass transfer approach show that when a very high concentration of alcohol is injected, the DNAPL/water/alcohol mixture forms a single phase and local mass transfer limitations become irrelevant. The field simulations were carried out in three steps. At the first level, a simple uncalibrated layered model is developed. This model is capable of roughly reproducing the production well concentrations of alcohol, but not of PCE. A more refined (but uncalibrated) permeability model is able to accurately simulate the breakthrough concentrations of injected alcohol from the production wells, but is unable to accurately predict the PCE removal. The final model uses a calibration of the initial PCE distribution to get good matches with the PCE effluent curves from the extraction wells. It is evident that the effectiveness of DNAPL source zone remediation is mainly affected by characteristics of the spatial heterogeneity of porous media and the variable (and unknown) DNAPL distribution. The inherent uncertainty in the DNAPL distribution at real field sites means that some form of calibration of the initial contaminant distribution will almost always be required to match contaminant effluent breakthrough curves.
ISSN:0169-7722
1873-6009
DOI:10.1016/j.jconhyd.2007.09.005