Abstract
Subsurface DNAPL (dense non-aqueous phase liquid) contamination from (un-) intentional spilling typically leads to severe environmental hazards. A large number of studies have demonstrated the relevance of DNAPL source zone geometry for the determination of contaminant plume propagation in groundwater. Optical imaging represents a promising non-invasive method for identifying DNAPL saturation without disturbing multiphase flow dynamics. However, workflow and image analysis methodologies have not been sufficiently developed or described for general application to related experimental efforts. For example, the choice of dye(s) used for phase colorization affects image processing and can bias final estimations of DNAPL saturations. In this study, we perform a series of DNAPL migration and entrapment studies in transparent tanks that are filled with three different types of porous media. Different dyes are used and raw images are acquired. Subsequently, these are used to evaluate a suite of image processing and analysis approaches, which are organized into a workflow. Our approach allows for us to identify key image processing and analysis steps that introduce the most error. Applicable dye configurations led to uncertainties of up to 41% depending on the selection of processing steps. Based on these findings, it was possible to delineate a flexible framework for image processing and analysis that has the potential for transfer and application in other tank experiment setups.
Highlights
The contamination of groundwater by dense non-aqueous phase liquids (DNAPLs) poses tremendous risks for secure water supply and natural environments (e.g., [1,2])
A large number of studies have demonstrated the relevance of DNAPL source zone geometry for the determination of contaminant plume propagation in groundwater
We perform a series of DNAPL migration and entrapment studies in transparent tanks that are filled with three different types of porous media
Summary
The contamination of groundwater by dense non-aqueous phase liquids (DNAPLs) poses tremendous risks for secure water supply and natural environments (e.g., [1,2]). Typical DNAPLs are chlorinated solvents that are used in degreasing and cleaning operations They are often toxic, carcinogenic, and highly persistent in the environment. Once DNAPL release from the original spill source has ceased, DNAPL migration will eventually end and a quasi-steady-state DNAPL source zone geometry (SZG; i.e., regions of non-wetting phase covering residual and elevated values for saturation) will form (e.g., [6,7]). Converting by using adaptive thresholding algorithm using percent distance between peaks. Converting to b/w using specific threshold Mesh overlay Defining mean threshold for background and object of interest [72,85]
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