Type of Document Dissertation Author Waddill, Dan Wilson Author's Email Address waddill@andassoc.com URN etd-1898-161425 Title Three-Dimensional Modeling of Solute Transport with In Situ Bioremediation Based on Sequential Electron Acceptors Degree Doctor of Philosophy Department Civil Engineering Advisory Committee
Advisor Name Title Mark A. Widdowson Committee Chair G. V. Loganathan Committee Member Jack C. Parker Committee Member Nancy G. Love Committee Member William E. Cox Committee Member Keywords
- sequential electron acceptors
- contaminant transport
- biodegradation
- microbial growth
- groundwater
Date of Defense 1998-01-29 Availability restricted Abstract A numerical model for subsurface solute transport is developed and applied to acontaminated field site. The model is capable of depicting multiple species transport in a
three-dimensional, anisotropic, heterogeneous domain as influenced by advection,
dispersion, adsorption, and biodegradation. Various hydrocarbon contaminants are
simulated as electron donors for microbial growth, with electron acceptors utilized in the
following sequence: oxygen, nitrate, Mn(IV), Fe(III), sulfate, and CO2. In addition, the
model accounts for products of biodegradation such as Mn (II), Fe(II), H2S, and CH4.
Biodegradation of each hydrocarbon substrate follows Monod kinetics, modified to
include the effects of electron acceptor and nutrient availability. Inhibition functions
permit any electron acceptor to inhibit utilization of all other electron acceptors that
provide less Gibbs free energy to the microbes. The model assumes that Fe(III) and
Mn(IV) occur as solid phase ions, while the other electron acceptors are dissolved in the
aqueous phase. Microbial biomass is simulated as independent groups of heterotrophic
bacteria that exist as scattered microcolonies attached to the porous medium. Diffusional
limitations to microbial growth are assumed to be negligible.
In order to verify the accuracy of the computer code, the model was applied to simple,
hypothetical test cases, and the results were compared to analytical solutions. In addition,
a sensitivity analysis showed that variations in model inputs caused logical changes in
output. Finally, the capabilities of the model were tested by comparing model output to
observed concentrations of hydrocarbons, electron acceptors, and endproducts at a
leaking UST site. The model was calibrated using historical site data, and predictive
capabilities of the model were tested against subsequent sets of field data.
The model was used to examine the effect of porous media heterogeneities on contaminant
transport and biodegradation. The turning bands method was used to produce hypothetical,
yet realistic heterogeneous fields describing hydraulic conductivity, initial biomass
concentration, and the maximum rate of substrate utilization. When the available electron
acceptor concentrations were small compared to the hydrocarbon concentration, the
overall rate of hydrocarbon mass loss increased with time, even as hydrocarbon
concentrations decreased. This trend is the opposite of what would be predicted by a first
order decay model.
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