© The Author(s) 2015. This article is published with open access at Springerlink.com Abstract Currently, there are no tractable approaches available for modeling non-equilibrium mass exchange of a solute between water phase and biofilm in porous media. The present work contributes to a quantitative description of the mass exchange of a solute over a single pore domain under a wide range of prevailing conditions. First, we developed a semiempirical model for the rate of solute mass exchange between water phase and biofilm. Then, extensive microscale simulations in a single pore were conducted. Results were aver-aged over a single pore domain, in order to determine a tube-scale kinetic rate coefficient as a function of various transport and b...
Biofilms have been modeled as homogeneous layers of cells and extracellular polymers covered by a un...
In this paper, we derive a pore-scale model for permeable biofilm formation in a two-dimensional por...
In liquid−solid adsorption, fluid film diffusion is typically faster than intraparticle diffusion, e...
Currently, there are no tractable approaches available for modeling non-equilibrium mass exchange of...
In this work, we upscale a pore-scale description of mass transport in a porous medium containing bi...
International audienceWe develop a Darcy-scale model for multiphase transport in porous media coloni...
International audienceIn this work, we derive a Darcy-scale model for solute transport in porous med...
International audienceWe develop a one-equation non-equilibrium model to describe the Darcy-scale tr...
Many microorganisms live within surface-associated consortia, termed biofilms, that can form intrica...
Microbial activity and biofilm growth in porous media can drastically modify transport properties su...
In this paper, we derive upscaled equations for modeling biofilm growth in porous media. The resulti...
Many microorganisms live within surface-associated consortia, termed biofilms, that can form intrica...
The knowledge of mass transfer rates in microbial biofilms is often the limiting step on biofilm mo...
Abstract In this work, a pore-network (PN)model for solute transport and biofilm growth in porous me...
This thesis relates to the mathematical modelling of biofilm in two primary areas: biofilm growth, a...
Biofilms have been modeled as homogeneous layers of cells and extracellular polymers covered by a un...
In this paper, we derive a pore-scale model for permeable biofilm formation in a two-dimensional por...
In liquid−solid adsorption, fluid film diffusion is typically faster than intraparticle diffusion, e...
Currently, there are no tractable approaches available for modeling non-equilibrium mass exchange of...
In this work, we upscale a pore-scale description of mass transport in a porous medium containing bi...
International audienceWe develop a Darcy-scale model for multiphase transport in porous media coloni...
International audienceIn this work, we derive a Darcy-scale model for solute transport in porous med...
International audienceWe develop a one-equation non-equilibrium model to describe the Darcy-scale tr...
Many microorganisms live within surface-associated consortia, termed biofilms, that can form intrica...
Microbial activity and biofilm growth in porous media can drastically modify transport properties su...
In this paper, we derive upscaled equations for modeling biofilm growth in porous media. The resulti...
Many microorganisms live within surface-associated consortia, termed biofilms, that can form intrica...
The knowledge of mass transfer rates in microbial biofilms is often the limiting step on biofilm mo...
Abstract In this work, a pore-network (PN)model for solute transport and biofilm growth in porous me...
This thesis relates to the mathematical modelling of biofilm in two primary areas: biofilm growth, a...
Biofilms have been modeled as homogeneous layers of cells and extracellular polymers covered by a un...
In this paper, we derive a pore-scale model for permeable biofilm formation in a two-dimensional por...
In liquid−solid adsorption, fluid film diffusion is typically faster than intraparticle diffusion, e...
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