4.6 Article

Modeling Multidimensional and Multispecies Biofilms in Porous Media

Journal

BIOTECHNOLOGY AND BIOENGINEERING
Volume 114, Issue 8, Pages 1679-1687

Publisher

WILEY
DOI: 10.1002/bit.26292

Keywords

biofilm model; bioremediation; cellular automaton; pore scale; syntroph; uranium

Funding

  1. U.S. Department of Energy [DE-SC0006771]
  2. Florida State University [28886]
  3. U.S. Department of Energy (DOE) [DE-SC0006771] Funding Source: U.S. Department of Energy (DOE)

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Modeling multidimensional and multispecies biofilm in porous media at the pore scale is challenging due to the need to simultaneously track the microbial community in the biofilms and the interfaces between the biofilms and the fluid. Therefore, researchers usually assume that the model has only one dimension in space or has only one microbial species. This work uses bioremediation of U(VI)-contaminated groundwater as the context to develop a two-dimensional and multispecies biofilm model. The model simulates the transverse mixing zone in which U(VI) is mixed with propionate, a nutrient externally supplied to stimulate the growth of microorganisms. The model considers multiple interactions among fluid flow, transport and reaction of chemical species, and growth of biofilm. The biofilm consists of two types of active biomass (syntrophs and dissimilatory metal reducing bacteria [DMBR]) and inert biomass. The two types of active biomass collaboratively remove U(VI). The model outputs biomass distribution, chemical species concentrations, and fluid flow at the pore scale to fundamentally study the multiple interactions. The model also outputs the contaminant removal rate that can be potentially used for up-scaling studies. The simulated results are generally consistent with experimental observations from other studies in trend. The trend can be explained by the multiple interactions based on thermodynamics and microbial kinetics. (c) 2017 Wiley Periodicals, Inc.

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