Your search keyword '"Auradou, Harold"' showing total 151 results

1. Ostwald-like ripening in the two-dimensional clustering of passive particles induced by swimming bacteria

Author

Bouvard, Julien, Moisy, Frédéric, and Auradou, Harold

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Biological Physics

Abstract

Clustering passive particles by active agents is a promising route for fabrication of colloidal structures. Here, we report the dynamic clustering of micrometric beads in a suspension of motile bacteria. We characterize the coarsening dynamics for various bead sizes, surface fractions and bacterial concentrations. We show that the time scale $\tau$ for the onset of clustering is governed by the time of first encounter of diffusing beads. At large time ($t \gg \tau$), we observe a robust cluster growth as $t^{1/3}$, similar to the Ostwald ripening mechanism. From bead tracking measurements, we extract the short-range bacteria-induced attractive force at the origin of this clustering.

Published

2023

2. Dispersion of motile bacteria in a porous medium

Author

Dentz, Marco, Creppy, Adama, Douarche, Carine, Clément, Eric, and Auradou, Harold

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics, 76S05, 60K50

Abstract

Understanding flow and transport of bacteria in porous media is crucial to technologies such as bioremediation, biomineralization or enhanced oil recovery. While physicochemical bacteria filtration is well-documented, recent studies showed that bacterial motility plays a key role in the transport process. Flow and transport experiments performed in microfluidic chips containing randomly placed obstacles confirmed that the distributions of non-motile particles stays compact, whereas for the motile strains, the distributions are characterized by both significant retention as well as fast downstream motion. For motile bacteria, the detailed microscopic study of individual bacteria trajectories reveals two salient features: (i) the emergence of an active retention process triggered by motility, (ii) enhancement of dispersion due to the exchange between fast flow channels and low flow regions in the vicinity of the solid grains. We propose a physical model based on a continuous time random walk approach. This approach accounts for bacteria dispersion via variable pore-scale flow velocities through a Markov model for equidistant particle speeds. Motility of bacteria is modeled by a two-rate trapping process that accounts for the motion towards and active trapping at the obstacles. This approach captures the forward tails observed for the distribution of bacteria displacements, and quantifies an enhanced hydrodynamic dispersion effect that originates in the interaction between flow at the pore-scale and bacterial motility. The model reproduces the experimental observations, and predicts bacteria dispersion and transport at the macroscale., Comment: 30 pages, 10 figures

Published

2022

3. Run-to-Tumble Variability Controls the Surface Residence Times of ${\it E.~coli}$ Bacteria

Author

Junot, Gaspard, Darnige, Thierry, Lindner, Anke, Martinez, Vincent A., Arlt, Jochen, Dawson, Angela, Poon, Wilson C. K., Auradou, Harold, and Clément, Eric

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Biological Physics

Abstract

Motile bacteria are known to accumulate at surfaces, eventually leading to changes in bacterial motility and bio-film formation. We use a novel two-colour, three-dimensional Lagrangian tracking technique, to follow simultaneously the body and the flagella of a wild-type ${\it Escherichia~coli}$. We observe long surface residence times and surface escape corresponding mostly to immediately antecedent tumbling. A motility model accounting for a large behavioural variability in run-time duration, reproduces all experimental findings and gives new insights into surface trapping efficiency.

Published

2021

4. Single-Trajectory Characterization of Active Swimmers in a Flow

Author

Junot, Gaspard, Clément, Eric, Auradou, Harold, and García-García, Reinaldo

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Biological Physics

Abstract

We develop a maximum likelihood method to infer relevant physical properties of elongated active particles. Using individual trajectories of advected swimmers as input, we are able to accurately determine their rotational diffusion coefficients and an effective measure of their aspect ratio, also providing reliable estimators for the uncertainties of such quantities. We validate our theoretical construction using numerically generated active trajectories upon no-flow, simple shear, and Poiseuille flow, with excellent results. Being designed to rely on single-particle data, our method eases applications in experimental conditions where swimmers exhibit a strong morphological diversity. We briefly discuss some of such ongoing experimental applications, specifically, in the characterization of swimming E.coli in a flow.

Published

2020

5. The Influence of Motility on Bacterial Accumulation in a Microporous Channel

Author

Lee, Miru, Lohrmann, Christoph, Szuttor, Kai, Auradou, Harold, and Holm, Christian

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics, Physics - Biological Physics, Physics - Fluid Dynamics

Abstract

We study the transport of bacteria in a porous media modeled by a square channel containing one cylindrical obstacle via molecular dynamics simulations coupled to a lattice Boltzmann fluid. Our bacteria model is a rod-shaped rigid body which is propelled by a force-free mechanism. To account for the behavior of living bacteria, the model also incorporates a run-and-tumble process. The model bacteria are capable of hydrodynamically interacting with both of the channel walls and the obstacle. This enables the bacteria to get reoriented when experiencing a shear-flow. We demonstrate that this model is capable of reproducing the bacterial accumulation on the rear side of an obstacle, as has recently been experimentally observed by [G. L. Mino, et al., Advances in Microbiology 8, 451 (2018)] using E.coli bacteria. By systematically varying the external flow strength and the motility of the bacteria, we resolve the interplay between the local flow strength and the swimming characteristics that lead to the accumulation. Moreover, by changing the geometry of the channel, we also reveal the important role of the interactions between the bacteria and the confining walls for the accumulation process., Comment: 10 pages, 9 figures, 3 videos, 1 supplementary information

Published

2020

6. Swimming bacteria in Poiseuille flow: the quest for active Bretherton-Jeffery trajectories

Author

Junot, Gaspard, Figueroa-Morales, Nuris, Darnige, Thierry, Lindner, Anke, Soto, Rodrigo, Auradou, Harold, and Clément, Eric

Subjects

Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter

Abstract

Using a 3D Lagrangian tracking technique, we determine experimentally the trajectories of non-tumbling E. coli mutants swimming in a Poiseuille flow. We identify a typology of trajectories in agreement with a kinematic "active Bretherton-Jeffery" model, featuring an axi-symmetric self-propelled ellipsoid. In particular, we recover the "swinging" and "shear tumbling" kinematics predicted theoretically by Z\"ottl et al. Moreover using this model, we derive analytically new features such as quasi-planar piece-wise trajectories, associated with the high aspect ratio of the bacteria, as well as the existence of a drift angle around which bacteria perform closed cyclic trajectories. However, the agreement between the model predictions and the experimental results remains local in time, due to the presence of Brownian rotational noise.

Published

2019

7. Effect of motility on the transport of bacteria populations through a porous medium

Author

Creppy, Adama, Clément, Eric, Douarche, Carine, D'Angelo, Maria Veronica, and Auradou, Harold

Subjects

Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter, Physics - Biological Physics

Abstract

The role of activity on the hydrodynamic dispersion of bacteria in a model porous medium is studied by tracking thousands of bacteria in a microfluidic chip containing randomly placed pillars. We first evaluate the spreading dynamics of two populations of motile and non-motile bacteria injected at different flow rates. In both cases, we observe that the mean and the variance of the distances covered by the bacteria vary linearly with time and flow velocity, a result qualitatively consistent with the standard geometric dispersion picture. However, quantitatively, the motiles bacteria display a systematic retardation effect when compared to the non-motile ones. Furthermore, the shape of the traveled distance distribution in the flow direction differs significantly for both the motile and the non-motile strain, hence probing a markedly different exploration process. For the non-motile bacteria, the distribution is Gaussian whereas for the motile ones, the distribution displays a positive skewness and spreads exponentially downstream akin to a Gamma distribution. The detailed microscopic study of the trajectories reveals two salient effects characterizing the exploration process of motile bacteria : (i) The emergence of an "active" retention effect due to an extended exploration of the pore surfaces, (ii) an enhanced spreading at the forefront due to the transport of bacteria along "fast-tracks" where they acquire a velocity larger than the local flow velocity. We finally discuss the practical applications of these effects on the large-scale macroscopic transfer and contamination processes caused by microbes in natural environments., Comment: 10 pages, 10 figures

Published

2018

8. Large scale flow visualization and anemometry applied to lab on chip models of porous media

Author

Paiola, Johan, Auradou, Harold, and Bodiguel, Hugues

Subjects

Physics - Fluid Dynamics

Abstract

The following is a report on an experimental technique allowing to quantify and map the velocity field with a very high resolution and a simple equipment in large 2D devices. A simple Shlieren technique is proposed to reinforce the contrast in the images and allow you to detect seeded particles that are pixel-sized or even inferior to it. The velocimetry technique that we have reported on is based on auto-correlation functions of the pixel intensity, which we have shown are directly related to the magnitude of the local average velocity. The characteristic time involved in the decorrelation of the signal is proportional to the tracer size and inversely proportional to the average velocity. We have reported on a detailed discussion about the optimization of relevant involved parameters, the spatial resolution and the accuracy of the method. The technique is then applied to a model porous media made of a random channel network. We show that it is highly efficient to determine the magnitude of the flow in each of the channels of the network, opening the road to the fundamental study of the flows of complex fluids. The latter is illustrated with yield stress fluid, in which the flow becomes highly heterogeneous at small flow rates.

Published

2016

9. Turning bacteria suspensions into a 'superfluid'

Author

López, Héctor Matías, Gachelin, Jérémie, Douarche, Carine, Auradou, Harold, and Clément, Eric

Subjects

Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter

Abstract

The rheological response under simple shear of an active suspension of Escherichia coli is determined in a large range of shear rates and concentrations. The effective viscosity and the time scales characterizing the bacterial organization under shear are obtained. In the dilute regime, we bring evidences for a low shear Newtonian plateau characterized by a shear viscosity decreasing with concentration. In the semi-dilute regime, for particularly active bacteria, the suspension display a "super-fluid" like transition where the viscous resistance to shear vanishes, thus showing that macroscopically, the activity of pusher swimmers organized by shear, is able to fully overcome the dissipative effects due to viscous loss.

Published

2015

10. Effect of the porosity on the fracture surface roughness of sintered materials: From anisotropic to isotropic self-affine scaling

Author

Cambonie, Tristan, Bares, Jonathan, Hattali, Lamine, Bonamy, Daniel, Lazarus, Véronique, and Auradou, Harold

Subjects

Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter

Abstract

To unravel how the microstructure affects the fracture surface roughness in heterogeneous brittle solids like rocks or ceramics, we characterized the roughness statistics of post-mortem fracture surfaces in home-made materials of adjustable microstructure length-scale and porosity, obtained by sintering monodisperse polystyrene beads. Beyond the characteristic size of disorder, the roughness profiles are found to exhibit self-affine scaling features evolving with porosity. Starting from a null value and increasing the porosity, we quantitatively modify the self-affine scaling properties from anisotropic (at low porosity) to isotropic (for porosity larger than 10 %)., Comment: 10 pages, 10 figures, Physical Review E in Jan 2015, Vol. 91 Issue 1

Published

2015

11. A combined rheometry and imaging study of viscosity reduction in bacterial suspensions

Author

Martinez, Vincent A., Clement, Eric, Arlt, Jochen, Douarche, Carine, Dawson, Angela, Schwarz-Linek, Jana, Creppy, Adama K., Skultety, Viktor, Morozov, Alexander N., Auradou, Harold, and Poon, Wilson C. K.

Published

2020

12. Transverse and lateral confinement effects on the oscillations of a free cylinder in a viscous flow

Author

Gianorio, Luciano, D'Angelo, Maria Veronica, Cachile, Mario, Hulin, Jean-Pierre, and Auradou, Harold

Subjects

Physics - Fluid Dynamics

Abstract

The different types of instabilities of free cylinders (diameter $D$, length $L$) have been studied in a viscous flow (velocity $U$) between parallel vertical walls of horizontal width $W$ at a distance $H$: the influence of the confinement parameters $D/H$ and $L/W$ has been investigated. As $D/H$ increases, there is a transition from stable flow to oscillations transverse to the walls and then to a fluttering motion with oscillations of the angle of the axis with respect to the horizontal. The two types of oscillations may be superimposed in the transition domain. The frequency $f$ of the transverse oscillations is independent of the lateral confinement $L/W$ in the range: 0.055 \le L/W \le 0.94$ for a given cylinder velocity $V_{cx}$ and increases only weakly with $V_{cx}$. These results are accounted for by assuming a 2D local flow over the cylinder with a characteristic velocity independent of $L/W$ for a given $V_{cx}$ value. The experimental values of $f$ are also independent of the transverse confinement $D/H$. The frequency $f_f$ of the fluttering motion is significantly lower than $f$: $f_f$ is also nearly independent of the cylinder diameter and of the flow velocity but decreases significantly as $L/W$ increases. The fluttering instability is then rather a 3D phenomenon involving the full length of the cylinder and the clearance between its ends and the side walls.

Published

2013

13. Self-Sustained Reaction Fronts in Porous Media

Author

Atis, Severine, Saha, Sandeep, Auradou, Harold, Salin, Dominique, and Talon, Laurent

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Physics - Fluid Dynamics

Abstract

We analyze experimentally chemical waves propagation in the disordered flow field of a porous medium. The reaction fronts travel at a constant velocity which drastically depends on the mean flow direction and rate. The fronts may propagate either downstream and upstream but, surprisingly, they remain static over a range of flow rate values. Resulting from the competition between the chemical reaction and the disordered flow field, these frozen fronts display a particular sawtooth shape. The frozen regime is likely to be associated with front pinning in low velocity zones, the number of which varies with the ratio of the mean flow and the chemical front velocities., Comment: 4 pages, 5 figures

Published

2012

14. Relation Between First Arrival Time and Permeability in Self-Affine Fractures with Areas in Contact

Author

Talon, Laurent, Auradou, Harold, and Hansen, Alex

Subjects

Physics - Fluid Dynamics

Abstract

We demonstrate that the first arrival time in dispersive processes in self-affine fractures are governed by the same length scale characterizing the fractures as that which controls their permeability. In one-dimensional channel flow this length scale is the aperture of the bottle neck, i.e., the region having the smallest aperture. In two dimensions, the concept of a bottle neck is generalized to that of a minimal path normal to the flow. The length scale is then the average aperture along this path. There is a linear relationship between the first arrival time and this length scale, even when there is strong overlap between the fracture surfaces creating areas with zero permeability. We express the first arrival time directly in terms of the permeability., Comment: EPL (2012) 1

Published

2012

15. Oscillations and translation of a free cylinder in a confined flow

Author

D'Angelo, Maria Veronica, Hulin, Jean-Pierre, and Auradou, Harold

Subjects

Physics - Fluid Dynamics

Abstract

An oscillatory instability has been observed experimentally on an horizontal cylinder free to move and rotate between two parallel vertical walls of distance H; its characteristics differ both from vortex shedding driven oscillations and from those of tethered cylinders in the same geometry. The vertical motion of the cylinder, its rotation about its axis and its transverse motion across the gap have been investigated as a function of its diameter D, its density s, of the mean vertical velocity U of the fluid and of its viscosity. For a blockage ratio D/H above 0.5 and a Reynolds number Re larger then 14, oscillations of the rolling angle of the cylinder about its axis and of its transverse coordinate in the gap are observed together with periodic variations of the vertical velocity. Their frequency f is the same for the sedimentation of the cylinder in a static fluid (U = 0) and for a non-zero mean flow (U 6= 0). The Strouhal number St associated to the oscillation varies as 1/Re with : St.Re = 3 $\pm$ 0.15. The corresponding period 1/f is then independent of U and corresponds to a characteristic viscous diffusion time over a distance ~ D, implying a strong influence of the viscosity. These characteristics differ from those of vortex shedding and tethered cylinders for which St is instead roughly constant with Re and higher than here.

Published

2012

16. Stokes flow paths separation and recirculation cells in X-junctions of varying angle

Author

Cachile, Mario, Talon, Laurent, Gomba, Juan M., Hulin, Jean-Pierre, and Auradou, Harold

Subjects

Physics - Fluid Dynamics

Abstract

Fluid and solute transfer in X-junctions between straight channels is shown to depend critically on the junction angle in the Stokes flow regime. Experimentally, water and a water-dye solution are injected at equal flow rates in two facing channels of the junction: Planar Laser Induced fluorescence (PLIF) measurements show that the largest part of each injected fluid "bounces back" preferentially into the outlet channel at the lowest angle to the injection; this is opposite to the inertial case and requires a high curvature of the corresponding streamlines. The proportion of this fluid in the other channel decreases from 50% at 90\degree to zero at a threshold angle. These counterintuitive features reflect the minimization of energy dissipation for Stokes flows. Finite elements numerical simulations of a 2D Stokes flow of equivalent geometry con rm these results and show that, below the threshold angle 33.8\degree recirculation cells are present in the center part of the junction and separate the two injected flows of the two solutions. Reducing further leads to the appearance of new recirculation cells with lower flow velocities.

Published

2012

17. Permeability Estimates of Self-Affine Fracture Faults Based on Generalization of the Bottle Neck Concept

Author

Talon, Laurent, Auradou, Harold, and Hansen, Alex

Subjects

Physics - Fluid Dynamics

Abstract

We propose a method for calculating the effective permeability of two-dimensional self-affine permeability fields based on generalizing the one-dimensional concept of a bottleneck. We test the method on fracture faults where the local permeability field is given by the cube of the aperture field. The method remains accurate even when there is substantial mechanical overlap between the two fracture surfaces. The computational efficiency of the method is comparable to calculating a simple average and is more than two orders of magnitude faster than solving the Reynolds equations using a finite-difference scheme.

Published

2010

18. Analytical shape determination of fiber-like objects with Virtual Image Correlation

Author

Semin, Benoit, François, Marc Louis Maurice, and Auradou, Harold

Subjects

Computer Science - Computer Vision and Pattern Recognition, Physics - Computational Physics

Abstract

This paper reports a method allowing for the determination of the shape of deformed fiber-like objects. Compared to existing methods, it provides analytical results including the local slope and curvature which are of first importance, for instance, in beam mechanics. The presented VIC (Virtual Image Correlation) method consists in looking for the best correlation between the image of the fiber-like object and a virtual beam image, using an algorithm close to the Digital Image Correlation method developed in experimental solid mechanics. The computation only involves the part of the image in the vicinity of the fiber: the method is thus insensitive to the picture background and the computational cost remains low. Two examples are reported: the first proves the precision of the method, the second its ability to identify a complex shape with multiple loops., Comment: 17 pages

Published

2010

19. Influence of flow confinement on the drag force on a static cylinder

Author

Semin, Benoît, Hulin, Jean-Pierre, and Auradou, Harold

Subjects

Physics - Fluid Dynamics

Abstract

The influence of confinement on the drag force $F$ on a static cylinder in a viscous flow inside a rectangular slit of aperture $h_0$ has been investigated from experimental measurements and numerical simulations. At low enough Reynolds numbers, $F$ varies linearly with the mean velocity and the viscosity, allowing for the precise determination of drag coefficients $\lambda_{||}$ and $\lambda_{\bot}$ corresponding respectively to a mean flow parallel and perpendicular to the cylinder length $L$. In the parallel configuration, the variation of $\lambda_{||}$ with the normalized diameter $\beta = d/h_0$ of the cylinder is close to that for a 2D flow invariant in the direction of the cylinder axis and does not diverge when $\beta = 1$. The variation of $\lambda_{||}$ with the distance from the midplane of the model reflects the parabolic Poiseuille profile between the plates for $\beta \ll 1$ while it remains almost constant for $\beta \sim 1$. In the perpendicular configuration, the value of $\lambda_{\bot}$ is close to that corresponding to a 2D system only if $\beta \ll 1$ and/or if the clearance between the ends of the cylinder and the side walls is very small: in that latter case, $\lambda_{\bot}$ diverges as $\beta \to 1$ due to the blockage of the flow. In other cases, the side flow between the ends of the cylinder and the side walls plays an important part to reduce $\lambda_{\bot}$: a full 3D description of the flow is needed to account for these effects.

Published

2009

20. Geometrical and transport properties of single fractures: influence of the roughness of the fracture walls

Author

Auradou, Harold

Subjects

Physics - Geophysics

Abstract

This article reviews the main features of the transport properties of single fractures. A particular attention paid to fractures in geological materials which often display a roughness covering a broad range of length scales. Because of the small distance separating the fracture walls, the surface roughness is a key parameter influencing the structure of the void space. Studies devoted to the characterization of the surface roughness are presented as well as works aimed at characterizing the void space geometry. The correlation of the free space is found to be crucially function of the failure mechanism (brittle, quasi brittle or plastic...) but also of possible shear displacements during the failure. The influence of the surface roughness on the mechanical behavior of fractures under a normal load and a shear stress is also described. Finally, experimental, numerical and theoretical works devoted to the study of the influence of the fracture void geometry on the permeability and on the hydrodynamic dispersion of a dissolved species are discussed.

Published

2009

21. Miscible transfer of solute in different types of rough fractures: from random to multiscale fracture walls heights

Author

Auradou, Harold, Boschan, Alejandro, Chertcoff, Ricardo, D'Angelo, Maria Veronica, Hulin, Jean-Pierre, and Ippolito, Irene

Subjects

Physics - Fluid Dynamics, Physics - Geophysics

Abstract

Miscible tracer dispersion measurements in transparent model fractures with different types of wall roughness are reported. The nature (Fickian or not) of dispersion is determined by studying variations of the mixing front as a function of the traveled distance but also as a function of the lateral scale over which the tracer concentration is averaged. The dominant convective dispersion mechanisms (velocity profile in the gap, velocity variations in the fracture plane) are established by comparing measurements using Newtonian and shear thinning fluids. For small monodisperse rugosities, front spreading is diffusive with a dominant geometrical dispersion (dispersion coefficient $D \propto Pe$) at low P\'eclet numbers $Pe$; at higher $Pe$ values one has either $D \propto Pe^2$ ({\it i.e.} Taylor dispersion) for obstacles of height smaller than the gap or $D \propto Pe^{1.35}$ for obstacles bridging the gap. For a self affine multiscale roughness like in actual rocks and a relative shear displacement $\vec{\delta}$ of complementary walls, the aperture field is channelized in the direction perpendicular to $\delta$. For a mean velocity $\vec{U}$ parallel to the channels, the global front geometry reflects the velocity contrast between them and is predicted from the aperture field. For $\vec{U}$ perpendicular to the channels, global front spreading is much reduced. Local spreading of the front thickness remains mostly controlled by Taylor dispersion except in the case of a very strong channelization parallel to $\vec U$.

Published

2009

22. Anisotropy of tracer dispersion in rough model fractures with sheared walls

Author

Boschan, Alejandro, Auradou, Harold, Ippolito, Irene, Chertcoff, Ricardo, and Hulin, Jean-Pierre

Subjects

Physics - Geophysics, Physics - Fluid Dynamics

Abstract

Dispersion experiments are compared for two transparent model fractures with identical complementary rough walls but with a relative shear displacement $\vec{\delta}$ parallel ($\vec{\delta}\parallel \vec{U}$) or perpendicular ($\vec{\delta} \perp \vec{U}$) to the flow velocity $\vec{U}$. The structure of the mixing front is characterized by mapping the local normalized local transit time $\bar t(x,y)$ and dispersivity $\alpha(x,y)$. For $\vec{\delta} \perp \vec{U}$, displacement fronts display large fingers: their geometry and the distribution of $\bar t(x,y)U/x$ are well reproduced by assuming parallel channels of hydraulic conductance deduced from the aperture field. For $\vec{\delta} \parallel \vec{U}$, the front is flatter and $\alpha(x,y)$ displays a narrow distribution and a Taylor-like variation with $Pe$.

Published

2008

23. Single fiber transport by a fluid flow in a fracture with rough walls: influence of the fluid rheology

Author

D'Angelo, Maria Veronica, Auradou, Harold, Picard, Guillemette, Poitzsch, Martin E., and Hulin, Jean-Pierre

Subjects

Physics - Fluid Dynamics

Abstract

The possible transport of fibers by fluid flow in fractures is investigated experimentally in transparent models using flexible polyester thread (mean diameter $280 \mu\mathrm{m}$) and Newtonian and shear thinning fluids. In the case of smooth parallel walls, fibers of finite length $\ell = 20-150 \mathrm{mm}$ move at a constant velocity of the order of the maximum fluid velocity in the aperture. In contrast, for fibers lying initially at the inlet side of the model and dragged by the flow inside it, the velocity increases with the depth of penetration (this results from the lower velocity - and drag - in the inlet part). In both cases, the friction of the fiber with the smooth walls is weak. For rough self-affine walls and a continuous gradient of the local mean aperture transverse to the flow, transport of the fibers by a water flow is only possible in the region of larger aperture ($\bar{a} \gtrsim 1.1 \mathrm{mm}$) and is of "stop and go" type at low velocities. Time dependent distorsions of the fiber are also often observed. When water is replaced by a shear thinning polymer solution, the fibers move faster and continuously in high aperture regions and their friction with the walls is reduced. Fiber transport becomes also possible in narrower regions where irreversible pinning occurred for water. In a third rough model with no global aperture gradient but with rough walls and a channelization parallel to the mean flow, fiber transport was only possible in shear-thinning flows and pinning and entanglement effects were studied.

Published

2008

24. Dispersion enhancement and damping by buoyancy driven flows in 2D networks of capillaries

Author

D'Angelo, Maria Veronica, Auradou, Harold, Allain, Catherine, Rosen, Marta, and Hulin, Jean-Pierre

Subjects

Physics - Fluid Dynamics

Abstract

The influence of a small relative density difference on the displacement of two miscible liquids is studied experimentally in transparent 2D networks of micro channels. Both stable displacements in which the denser fluid enters at the bottom of the cell and displaces the lighter one and unstable displacements in which the lighter fluid is injected at the bottom and displaces the denser one are realized. Except at the lowest mean flow velocity U, the average $C(x,t)$ of the relative concentration satisfies a convection-dispersion equation. The dispersion coefficient is studied as function of the relative magnitude of fluid velocity and of the velocity of buoyancy driven fluid motion. A model is suggested and its applicability to previous results obtained in 3D media is discussed.

Published

2008

25. Failure mechanisms and surface roughness statistics of fractured Fontainebleau sandstone

Author

Ponson, Laurent, Auradou, Harold, Pessel, Marc, Lazarus, Véronique, and Hulin, Jean-Pierre

Subjects

Condensed Matter - Statistical Mechanics

Abstract

In an effort to investigate the link between failure mechanisms and the geometry of fractures of compacted grains materials, a detailed statistical analysis of the surfaces of fractured Fontainebleau sandstones has been achieved. The roughness of samples of different widths W is shown to be self affine with an exponent zeta=0.46 +- 0.05 over a range of length scales ranging from the grain size d up to an upper cut-off length \xi = 0.15 W. This low zeta value is in agreement with measurements on other sandstones and on sintered materials. The probability distributions P(delta z,delta h) of the variations of height over different distances delta z > d can be collapsed onto a single Gaussian distribution with a suitable normalisation and do not display multifractal features. The roughness amplitude, as characterized by the height-height correlation over fixed distances delta z, does not depend on the sample width, implying that no anomalous scaling of the type reported for other materials is present. It is suggested, in agreement with recent theoretical work, to explain these results by the occurence of brittle fracture (instead of damage failure in materials displaying a higher value of zeta = 0.8)., Comment: 7 pages

Published

2007

26. Velocity contrasts enhancement for shear thinning solutions flowing in a rough fracture

Author

Auradou, Harold, Boschan, Alejandro, Chertcoff, Ricardo, Gabbanelli, Susana, Hulin, Jean-Pierre, and Ippolito, Irene

Subjects

Physics - Fluid Dynamics

Abstract

Flow and transport are studied in transparent model fractures with rough complementary self-affine walls with a relative shear displacement $\vec{u}$. The aperture field is shown to display long range correlations perpendicular to $\vec{u}$: for flow in that direction, the width and geometry of the front of a dyed shear-thinning polymer solution displacing a transparent one have been studied as a function of the fluid rheology and flow rate. The front width increases linearly with distance indicating a convection of the fluids with a low transverse mixing between the flow paths. The width also increases with the flow-rate as the fluid rheology shifts from Newtonian at low shear rates $\dot \gamma$ towards a shear thinning behaviour at higher $\dot \gamma$ values. The width also increases with the polymer concentration at high flow-rates. These results demonstrate the enhancement of the flow velocity contrasts between different flow channels for shear thinning fluids. The relative widths at low and high $\dot \gamma$ values for different polymer concentrations are well predicted by an analytical model considering the fracture as a set of parallel ducts of constant hydraulic apertures. The overall geometry of the experimental front geometry is also predicted by the theoretical model from the aperture map.

Published

2007

27. Pore scale mixing and macroscopic solute dispersion regimes in polymer flows inside 2D model networks

Author

D'Angelo, Maria Veronica, Auradou, Harold, Allain, Catherine, and Hulin, Jean-Pierre

Subjects

Physics - Fluid Dynamics, Physics - Classical Physics

Abstract

A change of solute dispersion regime with the flow velocity has been studied both at the macroscopic and pore scales in a transparent array of capillary channels using an optical technique allowing for simultaneous local and global concentration mappings. Two solutions of different polymer concentrations (500 and 1000 ppm) have been used at different P\'eclet numbers. At the macroscopic scale, the displacement front displays a diffusive spreading: for $Pe \leq 10$, the dispersivity $l\_d$ is constant with $Pe$ and increases with the polymer concentration; for $Pe > 10$, $l\_d$ increases as $Pe^{1.35}$ and is similar for the two concentrations. At the local scale, a time lag between the saturations of channels parallel and perpendicular to the mean flow has been observed and studied as a function of the flow rate. These local measurements suggest that the change of dispersion regime is related to variations of the degree of mixing at the junctions. For $Pe \leq 10$, complete mixing leads to pure geometrical dispersion enhanced for shear thinning fluids; for $Pe >10$ weaker mixing results in higher correlation lengths along flow paths parallel to the mean flow and in a combination of geometrical and Taylor dispersion.

Published

2006

28. Influence of the disorder on tracer dispersion in a flow channel

Author

Charette, Victor Javier, Evangelista, Elisa, Chertcoff, Ricardo, Auradou, Harold, Hulin, Jean-Pierre, and Ippolito, Irene

Subjects

Physics - Fluid Dynamics

Abstract

Tracer dispersion is studied experimentally in periodic or disordered arrays of beads in a capillary tube. Dispersion is measured from light absorption variations near the outlet following a steplike injection of dye at the inlet. Visualizations using dye and pure glycerol are also performed in similar geometries. Taylor dispersion is dominant both in an empty tube and for a periodic array of beads: the dispersivity $l\_d$ increases with the P\'eclet number $Pe$ respectively as $Pe$ and $Pe^{0.82}$ and is larger by a factor of 8 in the second case. In a disordered packing of smaller beads (1/3 of the tube diameter) geometrical dispersion associated to the disorder of the flow field is dominant with a constant value of $l\_d$ reached at high P\'eclet numbers. The minimum dispersivity is slightly higher than in homogeneous nonconsolidated packings of small grains, likely due heterogeneities resulting from wall effects. In a disordered packing with the same beads as in the periodic configuration, $l\_d$ is up to 20 times lower than in the latter and varies as $Pe^\alpha$ with $\alpha = 0.5$ or $= 0.69$ (depending on the fluid viscosity). A simple model accounting for this latter result is suggested., Comment: available online at http://www.edpsciences.org/journal/index.cfm?edpsname=epjap&niv1=contents&niv2=archives

Published

2006

29. Miscible displacement fronts of shear thinning fluids inside rough fractures

Author

Boschan, Alexandro, Auradou, Harold, Ippolito, Irene, Chertcoff, Ricardo, and Hulin, Jean-Pierre

Subjects

Physics - Fluid Dynamics

Abstract

The miscible displacement of a shear-thinning fluid by another of same rheological properties is studied experimentally in a transparent fracture by an optical technique imaging relative concentration distributions. The fracture walls have complementary self-affine geometries and are shifted laterally in the direction perpendicular to the mean flow velocity {\bf U} : the flow field is strongly channelized and macro dispersion controls the front structure for P\'{e}clet numbers above a few units. The global front width increases then linearly with time and reflects the velocity distribution between the different channels. In contrast, at the local scale, front spreading is similar to Taylor dispersion between plane parallel surfaces. Both dispersion mechanisms depend strongly on the fluid rheology which shifts from Newtonian to shear-thinning when the flow rate increases. In the latter domain, increasing the concentration enhances the global front width but reduces both Taylor dispersion (due to the flattening of the velocity profile in the gap of the fracture) and the size of medium scale front structures.

Published

2006

30. Low self-affine exponents of fracture surfaces of glass ceramics

Author

Ponson, Laurent, Auradou, Harold, Vié, Philippe, and Hulin, Jean-Pierre

Subjects

Condensed Matter - Statistical Mechanics

Abstract

The geometry of post mortem rough fracture surfaces of porous glass ceramics made of sintered glass beads is shown experimentally to be self-affine with an exponent zeta=0.40 (0.04) remarkably lower than the 'universal' value zeta=0.8 frequently measured for many materials. This low value of zeta is similar to that found for sandstone samples of similar micro structure and is also practically independent on the porosity phi in the range investigated (3% < phi < 26%) as well as on the bead diameter d and of the crack growth velocity. In contrast, the roughness amplitude normalized by d increases linearly with phi while it is still independent, within experimental error, of d and of the crack propagation velocity. An interpretation of this variation is suggested in terms of a transition from transgranular to intergranular fracture propagation with no influence, however, on the exponent zeta., Comment: 4 pages

Published

2006

31. Flow channelling in a single fracture induced by shear displacement

Author

Auradou, Harold, Drazer, German, Boschan, Alexandro, Hulin, Jean-Pierre, and Koplik, Joel

Subjects

Physics - Fluid Dynamics

Abstract

The effect on the transport properties of fractures of a relative shear displacement $\vec u$ of rough walls with complementary self-affine surfaces has been studied experimentally and numerically. The shear displacement $\vec u$ induces an anisotropy of the aperture field with a correlation length scaling as $u$ and significantly larger in the direction perpendicular to $\vec u$. This reflects the appearance of long range channels perpendicular to $\vec u$ resulting in a higher effective permeability for flow in the direction perpendicular to the shear. Miscible displacements fronts in such fractures are observed experimentally to display a self affine geometry of characteristic exponent directly related to that of the rough wall surfaces. A simple model based on the channelization of the aperture field allows to reproduces the front geometry when the mean flow is parallel to the channels created by the shear displacement.

Published

2006

32. Anisotropic self-affine properties of experimental fracture surfaces

Author

Ponson, Laurent, Bonamy, Daniel, Auradou, Harold, Mourot, Guillaume, Morel, Stéphane, Bouchaud, Elisabeth, Guillot, Claude, and Hulin, Jean-Pierre

Subjects

Condensed Matter - Statistical Mechanics

Abstract

The scaling properties of post-mortem fracture surfaces of brittle (silica glass), ductile (aluminum alloy) and quasi-brittle (mortar and wood) materials have been investigated. These surfaces, studied far from the initiation, were shown to be self-affine. However, the Hurst exponent measured along the crack direction is found to be different from the one measured along the propagation direction. More generally, a complete description of the scaling properties of these surfaces call for the use of the 2D height-height correlation function that involves three exponents zeta = 0.75, beta = 0.6 and z = 1.25 independent of the material considered as well as of the crack growth velocity. These exponents are shown to correspond to the roughness, growth and dynamic exponents respectively, as introduced in interface growth models. They are conjectured to be universal., Comment: 12 pages

Published

2006

33. Numerical study of the temperature and porosity effects on the fracture propagation in a 2D network of elastic bonds

Author

Auradou, Harold, Zei, Maria, and Bouchaud, Elisabeth

Subjects

Physics - Classical Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics

Abstract

This article reports results concerning the fracture of a 2d triangular lattice of atoms linked by springs. The lattice is submitted to controlled strain tests and the influence of both porosity and temperature on failure is investigated. The porosity is found on one hand to decrease the stiffness of the material but on the other hand it increases the deformation sustained prior to failure. Temperature is shown to control the ductility due to the presence of cavities that grow and merge. The rough surfaces resulting from the propagation of the crack exhibit self-affine properties with a roughness exponent $\zeta = 0.59 \pm 0.07$ over a range of length scales which increases with temperature. Large cavities also have rough walls which are found to be fractal with a dimension, $D$, which evolves with the distance from the crack tip. For large distances, $D$ is found to be close to 1.5, and close to 1.0 for cavities just before their coalescence with the main crack.

Published

2005

34. Using Microfluidic Set-Up to Determine the Adsorption Rate of Sporosarcina pasteurii Bacteria on Sandstone

Author

Marzin, Tom, Desvages, Brice, Creppy, Adama, Lépine, Louis, Esnault-Filet, Annette, and Auradou, Harold

Published

2020

35. Reversible and Irreversible Tracer Dispersion in an Oscillating Flow Inside a Model Rough Fracture

Author

Roht, Yanina Lucrecia, Chertcoff, Ricardo, Hulin, Jean-Pierre, Auradou, Harold, and Ippolito, Irene

Published

2018

36. Bacterial suspensions under flow

Author

Clement, Eric, Lindner, Anke, Douarche, Carine, and Auradou, Harold

Published

2016

37. Dispersion of motile bacteria in a porous medium

Author

Dentz, Marco, primary, Creppy, Adama, additional, Douarche, Carine, additional, Clément, Eric, additional, and Auradou, Harold, additional

Published

2022

38. Dispersion of motile bacteria in a porous medium

Author

Ministerio de Ciencia e Innovación (España), 0000-0002-3940-282X, 0000-0001-5216-8997, Dentz, Marco, Creppy, Adama, Douarche, Carine, Clément, Eric, Auradou, Harold, Ministerio de Ciencia e Innovación (España), 0000-0002-3940-282X, 0000-0001-5216-8997, Dentz, Marco, Creppy, Adama, Douarche, Carine, Clément, Eric, and Auradou, Harold

Abstract

Understanding flow and transport of bacteria in porous media is crucial to technologies such as bioremediation, biomineralization or enhanced oil recovery. While physicochemical bacteria filtration is well-documented, recent studies showed that bacterial motility plays a key role in the transport process. Flow and transport experiments performed in microfluidic chips containing randomly placed obstacles confirmed that the distributions of non-motile particles stays compact, whereas for the motile strains, the distributions are characterized by both significant retention as well as fast downstream motion. For motile bacteria, the detailed microscopic study of individual bacteria trajectories reveals two salient features: (i) the emergence of an active retention process triggered by motility, (ii) enhancement of dispersion due to the exchange between fast flow channels and low flow regions in the vicinity of the solid grains. We propose a physical model based on a continuous time random walk approach. This approach accounts for bacteria dispersion via variable pore-scale flow velocities through a Markov model for equidistant particle speeds. Motility of bacteria is modeled by a two-rate trapping process that accounts for the motion towards and active trapping at the obstacles. This approach captures the forward tails observed for the distribution of bacteria displacements, and quantifies an enhanced hydrodynamic dispersion effect that originates in the interaction between flow at the pore-scale and bacterial motility. The model reproduces the experimental observations, and predicts bacteria dispersion and transport at the macroscale.

Published

2022

39. Shaping gels and gels mixture to create helices

Author

D'Angelo, Maria Veronica, primary, Pauchard, Ludovic, additional, Auradou, Harold, additional, and Darbois Texier, Baptiste, additional

Published

2022

40. Run-to-Tumble Variability Controls the Surface Residence Times of E. coli Bacteria

Author

Junot, Gaspard, primary, Darnige, Thierry, additional, Lindner, Anke, additional, Martinez, Vincent A., additional, Arlt, Jochen, additional, Dawson, Angela, additional, Poon, Wilson C. K., additional, Auradou, Harold, additional, and Clément, Eric, additional

Published

2022

41. Dispersion of motile bacteria in a porous medium: Experimental data and theory

Author

Dentz, Marco, primary, Creppy, Adama, additional, Douarche, Carine, additional, Clément, Eric, additional, and Auradou, Harold, additional

Published

2022

42. Rheology of bacterial superfluids in viscous environments

Author

Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Chui, Jane YY, Douarche, Carine, Auradou, Harold, Juanes, Ruben, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Chui, Jane YY, Douarche, Carine, Auradou, Harold, and Juanes, Ruben

Abstract

Dense suspensions of pusher-type bacteria give rise to 'superfluids' in which the effective viscosity of the suspension is drastically reduced through collective motion, and in this study we investigate how a viscous environment affects this behavior.

Published

2021

43. Single-trajectory characterization of active swimmers in a flow

Author

Junot, Gaspard, primary, Clément, Eric, additional, Auradou, Harold, additional, and García-García, Reinaldo, additional

Published

2021

44. Modelization of dispersion of swimming bacteria in Poiseuille flow

Author

Ganesh, Akash, primary, Rescanieres, Romain, additional, Douarche, Carine, additional, and Auradou, Harold, additional

Published

2021

45. Rheology of bacterial superfluids in viscous environments

Author

Chui, Jane Y. Y., primary, Douarche, Carine, additional, Auradou, Harold, additional, and Juanes, Ruben, additional

Published

2021

46. The influence of motility on bacterial accumulation in a microporous channel

Author

Lee, Miru, primary, Lohrmann, Christoph, additional, Szuttor, Kai, additional, Auradou, Harold, additional, and Holm, Christian, additional

Published

2021

47. The effect of fracture roughness on the onset of non-linear flow

Author

Drazer, German, Cunningham, David, Auradou, Harold, and Shojaei-Zadeh, Shahab

Subjects

Physics::Fluid Dynamics, Surface roughness, Forchheimer, Inertial effects, Non-linear flow, Fractures, Critical Reynolds number

Abstract

In fractures where surface fluctuations are large compared to their aperture (narrow fractures) the flow is forced to move in tortuous paths that produce additional viscous friction and are subject to inertia effects. We consider the relation between the magnitude of surface roughness and the onset of inertial effects in the pressure driving the flow through a single open fracture. We performed experiments systematically varying the average aperture of the open fracture and covering a wide range of Reynolds numbers. For each aperture, we analyze the data in terms of the Forchheimer equation and show that the critical Reynolds number, defined as the Reynolds number at which inertial effects contribute 10% of the total pressure losses is highly correlated with the roughness of the surface. In particular, we show that significant inertial effects appear early as the relative importance of surface roughness increases. Finally, we present results showing that the magnitude of the deviations in the pressure field compared to a linear profile, taken at different points in the fracture along the flow direction,are directly related to the relative surface roughness of the fracture.

Published

2020

48. Swimming-induced non-Fickian transport of bacteria in porous media

Author

Dentz, Marco, primary, Auradou, Harold, additional, Creppy, Adama, additional, Clément, Eric, additional, and Carine, Douarche, additional

Published

2020

49. E coli Accumulation behind an Obstacle

Author

Miño, Gastón Leonardo, Baabour, Magali Denise, Chertcoff, Ricardo Héctor, Gutkind, Gabriel Osvaldo, Clément, Eric, Auradou, Harold, and Ippolito, Irene Paula

Subjects

purl.org/becyt/ford/1 [https], MICROFLUIDICS, Física de los Fluidos y Plasma, E COLI, MOTILITY, Ciencias Físicas, FILTRATION, purl.org/becyt/ford/1.3 [https], CIENCIAS NATURALES Y EXACTAS

Abstract

This paper describes our findings regarding the accumulation of motile bacte-ria at the rear of a confined obstacle and the physical description of the me-chanisms at play. We found that the modification of flow due to the presence of the obstacle produces vorticity that favor the diffusion of bacteria towards the downstream stagnation point. By testing different flow rates, we deter-mined the range in which bacteria accumulate. More interestingly, we observe that hydrodynamic interaction between the bacteria and the top and bottom surface of the microfluidic chip maintain the bacteria in the region where the flow velocity is lower than their own velocity. In the case of non-motile bacte-ria, this effect is not observed because bacteria follow the streamlines as pas-sive tracers do. Fil: Miño, Gastón Leonardo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro de Investigaciones y Transferencia de Entre Ríos. Universidad Nacional de Entre Ríos. Centro de Investigaciones y Transferencia de Entre Ríos; Argentina Fil: Baabour, Magali Denise. Universidad de Buenos Aires. Facultad de Ingeniería. Departamento de Física. Grupo de Medios Porosos; Argentina Fil: Chertcoff, Ricardo Héctor. Universidad de Buenos Aires. Facultad de Ingeniería. Departamento de Física. Grupo de Medios Porosos; Argentina Fil: Gutkind, Gabriel Osvaldo. Universidad de Buenos Aires. Facultad de Farmacia y Bioquímica; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay; Argentina Fil: Clément, Eric. Centre National de la Recherche Scientifique; Francia Fil: Auradou, Harold. Universite de Paris Xi. Laboratoire Automatiques et Systeme Thermiques; Francia Fil: Ippolito, Irene Paula. Universidad de Buenos Aires. Facultad de Ingeniería. Departamento de Física. Grupo de Medios Porosos; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina

Published

2018

50. Swimming bacteria in Poiseuille flow: The quest for active Bretherton-Jeffery trajectories

Author

Junot, Gaspard, primary, Figueroa-Morales, Nuris, additional, Darnige, Thierry, additional, Lindner, Anke, additional, Soto, Rodrigo, additional, Auradou, Harold, additional, and Clément, Eric, additional

Published

2019