Your search keyword '"Maxence Carrel"' showing total 2 results

1. Biofilms in 3D porous media: Delineating the influence of the pore network geometry, flow and mass transfer on biofilm development

Author

Rolf Kaufmann, Eberhard Morgenroth, Nicolas Derlon, Mario A. Beltran, Markus Holzner, Maxence Carrel, and Verónica L. Morales

Subjects

0301 basic medicine, Environmental Engineering, Materials science, Biofilm morphology, Flow (psychology), 010501 environmental sciences, Stress, 01 natural sciences, Wall shear stress, 03 medical and health sciences, Particle tracking velocimetry, Mass transfer, Shear stress, Three-dimensional porous medium, Composite material, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, X-ray micro computed tomography, Biofilm, Three-dimensional particle tracking velocimetry, Concentration boundary layer thickness, Ecological Modeling, X-Ray Microtomography, biochemical phenomena, metabolism, and nutrition, Mechanical, Pollution, Boundary layer, 030104 developmental biology, Biofilms, Hydrodynamics, Particle, Stress, Mechanical, Rheology, Porous medium, Porosity

Abstract

© 2018 Elsevier Ltd This study investigates the functional correspondence between porescale hydrodynamics, mass transfer, pore structure and biofilm morphology during progressive biofilm colonization of a porous medium. Hydrodynamics and the structure of both the porous medium and the biofilm are experimentally measured with 3D particle tracking velocimetry and micro X-ray Computed Tomography, respectively. The analysis focuses on data obtained in a clean porous medium after 36 h of biofilm growth. Registration of the particle tracking and X-ray data sets allows to delineate the interplay between porous medium geometry, hydrodynamic and mass transfer processes on the morphology of the developing biofilm. A local analysis revealed wide distributions of wall shear stresses and concentration boundary layer thicknesses. The spatial distribution of the biofilm patches uncovered that the wall shear stresses controlled the biofilm development. Neither external nor internal mass transfer limitations were noticeable in the considered system, consistent with the excess supply of nutrient and electron acceptors. The wall shear stress remained constant in the vicinity of the biofilm but increased substantially elsewhere.

Published

2018

2. Pore-Scale Hydrodynamics in a Progressively Bioclogged Three-Dimensional Porous Medium: 3-D Particle Tracking Experiments and Stochastic Transport Modeling

Author

Marco Dentz, Verónica L. Morales, Markus Holzner, Nicolas Derlon, Eberhard Morgenroth, and Maxence Carrel

Subjects

Materials science, Environmental Engineering, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Flow (psychology), education, 3‐D porous medium, 02 engineering and technology, 3-D-PTV, Biogeosciences, 01 natural sciences, Civil Engineering, biofilm, Physical Geography and Environmental Geoscience, Groundwater Hydrology, Exponential growth, Gamma distribution, correlated CTRW, Porosity, Research Articles, 0105 earth and related environmental sciences, Water Science and Technology, Groundwater Hydraulics, 3‐D‐PTV, Stochastic Hydrology, Mechanics, 020801 environmental engineering, Exponential function, Groundwater Transport, bioclogging, Flow velocity, anomalous transport, 3-D porous medium, Applied Economics, Hydrology, Porous medium, Continuous-time random walk, Bioremediation, Research Article

Abstract

Biofilms are ubiquitous bacterial communities that grow in various porous media including soils, trickling, and sand filters. In these environments, they play a central role in services ranging from degradation of pollutants to water purification. Biofilms dynamically change the pore structure of the medium through selective clogging of pores, a process known as bioclogging. This affects how solutes are transported and spread through the porous matrix, but the temporal changes to transport behavior during bioclogging are not well understood. To address this uncertainty, we experimentally study the hydrodynamic changes of a transparent 3‐D porous medium as it experiences progressive bioclogging. Statistical analyses of the system's hydrodynamics at four time points of bioclogging (0, 24, 36, and 48 h in the exponential growth phase) reveal exponential increases in both average and variance of the flow velocity, as well as its correlation length. Measurements for spreading, as mean‐squared displacements, are found to be non‐Fickian and more intensely superdiffusive with progressive bioclogging, indicating the formation of preferential flow pathways and stagnation zones. A gamma distribution describes well the Lagrangian velocity distributions and provides parameters that quantify changes to the flow, which evolves from a parallel pore arrangement under unclogged conditions, toward a more serial arrangement with increasing clogging. Exponentially evolving hydrodynamic metrics agree with an exponential bacterial growth phase and are used to parameterize a correlated continuous time random walk model with a stochastic velocity relaxation. The model accurately reproduces transport observations and can be used to resolve transport behavior at intermediate time points within the exponential growth phase considered., Key Points Experimental three‐dimensional particle tracking of flow tracers provides pore‐scale hydrodynamics in a progressively bioclogged porous mediumBiofilm growth induces formation of preferential flow paths and stagnation zones, leading to an increase of anomalous transportA continuous time random walk model based on a gamma distribution of the pore‐scale velocities captures transport dynamics

Published

2018