Upscaled modeling of complex DNAPL dissolution

A straightforward, upscaled DNAPL mass dissolution model is developed using relatively simple input consisting of characteristic dimensions and saturations of a DNAPL accumulation. Multiple accumulations are aggregated into a single source zone volume. Physically, the dissolution process is a combin...

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Bibliographic Details
Published in:Journal of contaminant hydrology 2022-01, Vol.244, p.103920-103920, Article 103920
Main Authors: Stewart, Lloyd D., Chambon, Julie C., Widdowson, Mark A., Kavanaugh, Michael C.
Format: Article
Language:English
Subjects:
Computer Simulation
Dissolution
Models, Theoretical
Multistage mass discharge
NAPL
Solubility
Source zone heterogeneity
Upscaled mass transfer
Water Pollutants, Chemical - analysis
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Summary:A straightforward, upscaled DNAPL mass dissolution model is developed using relatively simple input consisting of characteristic dimensions and saturations of a DNAPL accumulation. Multiple accumulations are aggregated into a single source zone volume. Physically, the dissolution process is a combination of flow through the mass (advective component) and flow around the mass (dispersive component). The contribution of each component is based on initial characteristic length scales and the average initial saturation. Changes over time with the depletion of mass are captured with a changing relative permeability and a power law relationship for the fraction of initial mass remaining. The utility of the upscaled process model is demonstrated with data from three studies: numerical simulation of multiple pools, two-dimensional test cell experiments with mixed architecture and with heterogeneous soil, and a controlled field study of multicomponent DNAPL release and depletion. Use of the model successfully reproduced the observed multistage mass discharge in each study and illuminated the governing processes. The power law exponent was relatively constant for the various conditions and relative permeability changes were integral to the success. The numerical and experimental studies were run to complete mass depletion which the upscaled model matched. The input parameters are minimal and are found in typical DNAPL source zone characterization data. [Display omitted] •Upscaled relationship of field parameters reproduces complex DNAPL mass discharge.•Field-scale dissolution correlation includes advective and dispersive components.•Demonstration with numerical and experimental data.•Successful field application to multicomponent DNAPL with complex architecture.
ISSN:0169-7722
1873-6009
DOI:10.1016/j.jconhyd.2021.103920