Your search keyword '"Laurent Talon"' showing total 33 results

1. Transient dispersion regimes in heterogeneous porous media: On the impact of spatial heterogeneity in permeability and exchange kinetics in mobile–immobile transport

Author

Laurent Talon, Emma Ollivier-Triquet, Marco Dentz, Daniela Bauer, and Ministerio de Ciencia e Innovación (España)

Subjects

Transient regimes, Ensure availability and sustainable management of water and sanitation for all, Mobile–Immobile model, Dispersion, Heterogeneity, Lattice Boltzmann, CTRW, Water Science and Technology

Abstract

Transport processes in the subsurface are coupled with the heterogeneity of the porous structure. Obtaining an accurate description of mass transport in such media at all time scales remains a crucial task, as the subsurface is strongly impacted by human activity. Spreading of pollutants in the transient but also in the asymptotic regime, as well as the time to reach a critical location (e.g. aquifer, well) significantly depend on the underlying heterogeneity of the permeability field. Moreover, in the case of solute retention, transport is also characterized by local exchange kinetics that depend on the local aquifer properties. Consequently, exchange (retention) times are expected to be spatially heterogeneous. In this work we focus on the influence of spatially heterogeneous permeability and exchange times on the transient and asymptotic transport regimes and provide a parametric study. To this goal, we simulate in a first part the transport in a two-dimensional heterogeneous medium under spatially varying permeability and mobile–immobile mass transfer parameters. Equations are solved using a Lattice-Boltzmann two-relaxation-time (TRT) algorithm. We assume the following relation between the local permeability K and the local exchange time: τ∝Kγ. Taking into account this relation, we investigate the impact of the Damköhler number (Da, ratio of the advection and exchange time scales), the disorder of the permeability field and the value of the exponent of the coupling function (γ) on the spatial evolution of the concentration field and breakthrough curve. We show that, depending on the parameters (Da, γ, etc.), we can observe transient, non-Fickian dispersion, which is characterized by non-exponential tails of the solute breakthrough curves and a non-linear evolution of the spatial variance of the solute distribution. In a second part, we present a new continuous time random walk (CTRW) model to upscale these transport behaviors. The model is based on a spatial Markov model for particle velocities that couples advective–dispersive transport and heterogeneous mass transfer through a compound Poisson process. The upscaled model can be fully parameterized by the statistics of permeability and the hydraulic gradient (with no fitting parameter), that is, in terms of medium and flow characteristics. The results of the CTRW model fully capture the non-Fickian transient transport regimes both for the breakthrough curves and spatial concentration variance. In the longtime limit, as expected from the central limit theorem, the CTRW model predicts normal, Fickian behavior. Finally we show, that the time to reach the asymptotic regimes in heterogeneous media (e.g. heterogeneous exchange times) is parameter dependent and in average is two orders of magnitude larger than for the respective homogeneous case. To summarize, the coupling between the heterogeneous permeability field and the local mass transfer properties can strongly influence transient and asymptotic transport regimes and potentially explain experimentally observed non-Gaussian behaviors., M.D. acknowledges the support of the Spanish Research Agency (10.13039/501100011033) and the Spanish Ministry of Science and Innovation through the grants CEX2018-000794-S and PID2019-106887GB-C31 (HydroPore).

Published

2023

2. Minimum principle for the flow of inelastic non-Newtonian fluids in macroscopic heterogeneous porous media

Author

Laurent Talon

Subjects

Fluid Flow and Transfer Processes, Modeling and Simulation, Computational Mechanics

Published

2022

3. On the determination of a generalized Darcy equation for yield stress fluid in porous media

Author

Laurent Talon

Published

2022

4. Low- and high-order accurate boundary conditions: From Stokes to Darcy porous flow modeled with standard and improved Brinkman lattice Boltzmann schemes

Author

Goncalo Silva, Irina Ginzburg, Laurent Talon, Hydrosystèmes et Bioprocédés (UR HBAN), Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), and Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics and Astronomy (miscellaneous), Discretization, LATTICE BOLTZMANN, Lattice Boltzmann methods, Geometry, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, EQUATION BRINKMAN, symbols.namesake, 0103 physical sciences, Resistance force, Boundary value problem, 0101 mathematics, Mathematics, Numerical Analysis, HIGH ORDER ACCURATE BOUNDARY SCHEMES, Applied Mathematics, Mathematical analysis, GRAY LBM, Mixed boundary condition, Finite element method, Computer Science Applications, 010101 applied mathematics, TRT BRINKMAN MODEL, Computational Mathematics, FEM BRINKMAN MODEL, Modeling and Simulation, Dirichlet boundary condition, [SDE]Environmental Sciences, symbols, Vector field

Abstract

International audience; The present contribution focuses on the accuracy of reflection-type boundary conditions in the Stokes-Brinkman-Darcy modeling of porous flows solved with the lattice Boltzmann method (LBM), which we operate with the two-relaxation-time (TRT) collision and the Brinkman-force based scheme (BF), called BF-TRT scheme. In parallel, we compare it with the Stokes-Brinkman-Darcy linear finite element method (FEM) where the Dirichlet boundary conditions are enforced on grid vertices. In bulk, both BF-TRT and FEM share the same defect: in their discretization a correction to the modeled Brinkman equation appears, given by the discrete Laplacian of the velocity-proportional resistance force. This correction modifies the effective Brinkman viscosity, playing a crucial role in the triggering of spurious oscillations in the bulk solution. While the exact form of this defect is available in lattice-aligned, straight or diagonal, flows; in arbitrary flow/lattice orientations its approximation is constructed. At boundaries, we verify that such a Brinkman viscosity correction has an even more harmful impact. Already at the first order, it shifts the location of the no-slip wall condition supported by traditional LBM boundary schemes, such as the bounce-back rule. For that reason, this work develops a new class of boundary schemes to prescribe the Dirichlet velocity condition at an arbitrary wall/boundary-node distance and that supports a higher order accuracy in the accommodation of the TRT-Brinkman solutions. For their modeling, we consider the standard BF scheme and its improved version, called IBF; this latter is generalized in this work to suppress or to reduce the viscosity correction in arbitrarily oriented flows. Our framework extends the one- and two-point families of linear and parabolic link-wise boundary schemes, respectively called B-LI and B-MLI, which avoid the interference of the Brinkman viscosity correction in their closure relations. The performance of LBM and FEM is thoroughly evaluated in three benchmark tests, which are run throughout three distinctive permeability regimes. The first configuration is a horizontal porous channel, studied with a symbolic approach, where we construct the exact solutions of FEM and BF/IBF with different boundary schemes. The second problem refers to an inclined porous channel flow, which brings in as new challenge the formation of spurious boundary layers in LBM; that is, numerical artefacts that arise due to a deficient accommodation of the bulk solution by the low-accurate boundary scheme. The third problem considers a porous flow past a periodic square array of solid cylinders, which intensifies the previous two tests with the simulation of a more complex flow pattern. The ensemble of numerical tests provides guidelines on the effect of grid resolution and the TRT free collision parameter over the accuracy and the quality of the velocity field, spanning from Stokes to Darcy permeability regimes. It is shown that, with the use of the high-order accurate boundary schemes, the simple, uniform-mesh-based TRT-LBM formulation can even surpass the accuracy of FEM employing hardworking body-fitted meshes.

Published

2017

5. Experimental and numerical determination of Darcy's law for yield stress fluids in porous media

Author

Daniela Bauer, Guillaume Batôt, Laurent Talon, Yannick Peysson, Marc Fleury, Thibaud Chevalier, H. B. Ly, IFP Energies nouvelles (IFPEN), Fluides, automatique, systèmes thermiques (FAST), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Fluid Flow and Transfer Processes, Materials science, Darcy's law, Computational Mechanics, Lattice Boltzmann methods, Mechanics, 01 natural sciences, 010305 fluids & plasmas, Volumetric flow rate, Sphere packing, Flow (mathematics), Modeling and Simulation, 0103 physical sciences, [PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph], 010306 general physics, Porous medium, Bingham plastic, Pressure gradient

Abstract

International audience; In this work, we studied experimentally and numerically the pressure–flow rate relationship for yield stress fluids in porous media. We developed and validated 3D numerical simulations of the velocity field via a lattice Boltzmann method based on the TRT scheme, and a specific experimental setup allowing yield stress fluids to flow in a closed-loop system to obtain stable rheological properties over a wide range of flow rates (4 decades). The porous medium studied experimentally is a sandstone. The flow properties were also simulated on a regular sphere packing and a random sphere packing as well as on a 3D geometry of a sandstone obtained by x-ray tomography. These different geometries allow highlighting the role of the heterogeneity of the pore structure on the flow properties. All results are expressed as the flow rate ˜Q versus the difference of the pressure gradient to the critical pressure (Δ˜P−Δ˜Pc); Pc defines the pressure below which there is no flow. We observed both numerically and experimentally three specific scaling regimes, already identified by Talon and Bauer [Eur. Phys. J. E 36, 139 (2013)] for a Bingham fluid in 2D porous media. We also evidenced the existence of two critical pressures: the “true” critical pressure ˜Pc defined as the pressure below which there is no flow and the “pseudo” critical pressure threshold ˜P∞c determined by fitting the data in the high-flow-rate regime. We show that the “true” critical pressure is always lower than the “pseudo” one in heterogeneous porous media and can be equal only in the case of regular porous structures. We explain these observations using an energy minimization principle.

Published

2019

6. Numerical study of Bingham flow in macrosopic two dimensional heterogenous porous media

Author

Laurent Talon, R. Kostenko, Fluides, automatique, systèmes thermiques (FAST), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), and Université Paris-Sud - Paris 11 (UP11)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Statistics and Probability, Physics, [PHYS.PHYS.PHYS-FLU-DYN]Physics [physics]/Physics [physics]/Fluid Dynamics [physics.flu-dyn], Scale (ratio), Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, Context (language use), Mechanics, Physics - Fluid Dynamics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Stress (mechanics), Physics::Fluid Dynamics, Fractal, Flow (mathematics), Macroscopic scale, 0103 physical sciences, 010306 general physics, Porous medium, Scaling

Abstract

The flow of non-Newtonian fluids is ubiquitous in many applications in the geological and industrial context. We focus here on yield stress fluids (YSF), i.e. a material that requires minimal stress to flow. We study numerically the flow of yield stress fluids in 2D porous media on a macroscopic scale in the presence of local heterogeneities. As with the microscopic problem, heterogeneities are of crucial importance because some regions will flow more easily than others. As a result, the flow is characterized by preferential flow paths with fractal features. These fractal properties are characterized by different scale exponents that will be determined and analyzed. One of the salient features of these results is that these exponents seem to be independent of the amplitude of heterogeneities for a log-normal distribution. In addition, these exponents appear to differ from those at the microscopic level, illustrating the fact that, although similar, the two scales are governed by different sets of equations.

Published

2019

7. Non-Darcy effects in fracture flows of a yield stress fluid

Author

A. Roustaei, Thibaud Chevalier, Laurent Talon, and Ian Frigaard

Subjects

Mechanical Engineering, Computation, Mechanics, Condensed Matter Physics, 01 natural sciences, Lubrication theory, 010305 fluids & plasmas, Nonlinear system, Flow (mathematics), Mechanics of Materials, 0103 physical sciences, Fracture (geology), Range (statistics), 010306 general physics, Porous medium, Pressure gradient, Geology

Abstract

We study non-inertial flows of single-phase yield stress fluids along uneven/rough-walled channels, e.g. approximating a fracture, with two main objectives. First, we re-examine the usual approaches to providing a (nonlinear) Darcy-type flow law and show that significant errors arise due to self-selection of the flowing region/fouling of the walls. This is a new type of non-Darcy effect not previously explored in depth. Second, we study the details of flow as the limiting pressure gradient is approached, deriving approximate expressions for the limiting pressure gradient valid over a range of different geometries. Our approach is computational, solving the two-dimensional Stokes problem along the fracture, then upscaling. The computations also reveal interesting features of the flow for more complex fracture geometries, providing hints about how to extend Darcy-type approaches effectively.

Published

2016

8. Variable density and viscosity, miscible displacements in horizontal Hele-Shaw cells. Part 1. Linear stability analysis

Author

Eckart Meiburg, Nisheet Goyal, and Laurent Talon

Subjects

Physics, Gravity (chemistry), Mechanical Engineering, Mechanics, Condensed Matter Physics, Instability, Physics::Fluid Dynamics, Gravitation, Viscosity, Nonlinear system, Gravitational field, Mechanics of Materials, Vertical direction, Displacement (fluid)

Abstract

A computational investigation of variable density and viscosity, miscible displacements in horizontal Hele-Shaw cells is presented. As a first step, two-dimensional base states are obtained by means of simulations of the Stokes equations, which are nonlinear due to the dependence of the viscosity on the local concentration. Here, the vertical position of the displacement front is seen to reach a quasisteady equilibrium value, reflecting a balance between viscous and gravitational forces. These base states allow for two instability modes: first, there is the familiar tip instability driven by the unfavourable viscosity contrast of the displacement, which is modulated by the presence of density variations in the gravitational field; second, a gravitational instability occurs at the unstably stratified horizontal interface along the side of the finger. Both of these instability modes are investigated by means of a linear stability analysis. The gravitational mode along the side of the finger is characterized by a wavelength of about one half to one full gap width. It becomes more unstable as the gravity parameter increases, even though the interface is shifted closer to the wall. The growth rate is largest far behind the finger tip, where the interface is both thicker, and located closer to the wall, than near the finger tip. The competing influences of interface thickness and wall proximity are clarified by means of a parametric stability analysis. The tip instability mode represents a gravity-modulated version of the neutrally buoyant mode. The analysis shows that in the presence of density stratification its growth rate increases, while the dominant wavelength decreases. This overall destabilizing effect of gravity is due to the additional terms appearing in the stability equations, which outweigh the stabilizing effects of gravity onto the base state.

Published

2013

9. Plane Poiseuille flow of miscible layers with different viscosities: instabilities in the Stokes flow regime

Author

Laurent Talon and Eckart Meiburg

Subjects

Materials science, Mechanical Engineering, Mechanics, Stokes flow, Condensed Matter Physics, Hagen–Poiseuille equation, Instability, Physics::Fluid Dynamics, symbols.namesake, Hele-Shaw flow, Mechanics of Materials, Stokes' law, symbols, Diffusion (business), Stokes number, Linear stability

Abstract

We investigate the linear stability of miscible, viscosity-layered Poiseuille flow. In the Stokes flow regime, diffusion is observed to have a destabilizing effect very similar to that of inertia in finite-Reynolds-number flows. For two-layer flows, four types of instability can dominate, depending on the interface location. Two interfacial modes exhibit large growth rates, while two additional bulk modes grow more slowly. Three-layer Stokes flows give rise to diffusive modes for each interface. These two diffusive interface modes can be in resonance, thereby enhancing the growth rate. Furthermore, modes without inertia and diffusion are also observed, consistent with a previous long-wave analysis for sharp interfaces. In contrast to that earlier investigation, the present analysis demonstrates that instability can also occur when the more viscous layer is in the centre, at larger wavenumbers.

Published

2011

10. Convective/absolute instability in miscible core-annular flow. Part 1: Experiments

Author

Laurent Talon, N. Rakotomalala, Jerome Martin, M. d’Olce, and Dominique Salin

Subjects

Convection, Physics, Mechanical Engineering, Rotational symmetry, Reynolds number, Thermodynamics, Injector, Radius, Mechanics, Condensed Matter Physics, Instability, law.invention, Volumetric flow rate, Core (optical fiber), symbols.namesake, Mechanics of Materials, law, symbols

Abstract

We address the issue of the convective or absolute nature of the instability of core-annular pipe flows, in experiments using two miscible fluids of equal density but different viscosities, the core fluid being much less viscous than the wall one. We use a concentric co-current injection of the two fluids. An axisymmetric parallel base state is obtained downstream the injector. The core radiusRIand the Reynolds numberReof the so-obtained base state are varied independently due to the control of the flow rate of each fluid. However, a downstream destabilization of this base state was observed within the explored range of the two control parametersRIandRe. Moreover, the fixed location of this destabilization, observed for some particular parameters, suggests an absolute nature of the instability. We present a tentative delineation of the nature (convective or absolute) of the instability and discuss the accessible measurements to experimentally address this issue.

Published

2009

11. Computation of the Equivalent Macroscopic Permeability Tensor of Discrete Networks with Heterogeneous Segment Length

Author

D. Bauer, Laurent Talon, and A. Ehrlacher

Subjects

Computer simulation, Water flow, Mechanical Engineering, Computation, Calculus, Representative elementary volume, Boundary value problem, Statistical physics, Anisotropy, Porous medium, Water Science and Technology, Civil and Structural Engineering, Mathematics, Network model

Abstract

Flow in discrete networks can be observed in biological, geological, or technical systems. Often, the number of individual segments is very large. Therefore, discrete pressure and flow calculation in each single segment becomes very time consuming, and a continuum model becomes attractive. We apply a global upscaling method based on a spatial average to investigate a porous media network model with heterogeneous pore length distribution. For this purpose, the porous media was modeled by triangular networks. For such networks, we characterize the representative elementary volume (REV) size and show that using window sizes smaller than the REV requires an heterogeneous Darcian description. We find that the permeability has to be distributed according to a log-Gaussian distribution with variance and correlation length depending on the window size and the porous microstructure. Finally, we apply the procedure to an anisotropic regular network for which an analytical solution can be found and show that using this method leads to the correct analytical behavior.

Published

2008

12. Moving line model and avalanche statistics of Bingham fluid flow in porous media

Author

Laurent Talon and Thibaud Chevalier

Subjects

Physics, Contact line, Line model, Biophysics, Complex system, Surfaces and Interfaces, General Chemistry, Mean field theory, Critical point (thermodynamics), Statistics, General Materials Science, Statistical physics, Porous medium, Bingham plastic, Scaling, Biotechnology

Abstract

In this article, we propose a simple model to understand the critical behavior of path opening during flow of a yield stress fluid in porous media as numerically observed by Chevalier and Talon (2015). This model can be mapped to the problem of a contact line moving in an heterogeneous field. Close to the critical point, this line presents an avalanche dynamic where the front advances by a succession of waiting time and large burst events. These burst events are then related to the non-flowing (i.e. unyielded) areas. Remarkably, the statistics of these areas reproduce the same properties as in the direct numerical simulations. Furthermore, even if our exponents seem to be close to the mean field universal exponents, we report an unusual bump in the distribution which depends on the disorder. Finally, we identify a scaling invariance of the cluster spatial shape that is well fit, to first order, by a self-affine parabola.

Published

2015

13. Publisher's Note: Generalization of Darcy's law for Bingham fluids in porous media: From flow-field statistics to the flow-rate regimes [Phys. Rev. E91, 023011 (2015)]

Author

Thibaud Chevalier and Laurent Talon

Subjects

Darcy's law, Generalization, Statistical physics, Porous medium, Flow field, Mathematics, Volumetric flow rate

Published

2015

14. Generalization of Darcy's law for Bingham fluids in porous media: From flow-field statistics to the flow-rate regimes

Author

Laurent Talon and Thibaud Chevalier

Subjects

Pressure drop, Darcy's law, Thermodynamics, Mechanics, Critical value, 01 natural sciences, Power law, 010305 fluids & plasmas, Permeability (earth sciences), 0103 physical sciences, 010306 general physics, Bingham plastic, Porous medium, Pressure gradient, Mathematics

Abstract

In this paper, we numerically investigate the statistical properties of the nonflowing areas of Bingham fluid in two-dimensional porous media. First, we demonstrate that the size probability distribution of the unyielded clusters follows a power-law decay with a large size cutoff. This cutoff is shown to diverge following a power law as the imposed pressure drop tends to a critical value. In addition, we observe that the exponents are almost identical for two different types of porous media. Finally, those scaling properties allow us to account for the quadratic relationship between the pressure gradient and velocity.

Published

2015

15. Analysis and improvement of Brinkman lattice Boltzmann schemes: Bulk, boundary, interface. Similarity and distinctness with finite elements in heterogeneous porous media

Author

Laurent Talon, Irina Ginzburg, and Goncalo Silva

Subjects

Physics::Fluid Dynamics, Permeability (earth sciences), Viscosity, Work (thermodynamics), Discretization, Mathematical analysis, Lattice Boltzmann methods, Geometry, Hagen–Poiseuille equation, Relative permeability, Finite element method, Mathematics

Abstract

This work focuses on the numerical solution of the Stokes-Brinkman equation for a voxel-type porous-media grid, resolved by one to eight spacings per permeability contrast of 1 to 10 orders in magnitude. It is first analytically demonstrated that the lattice Boltzmann method (LBM) and the linear-finite-element method (FEM) both suffer from the viscosity correction induced by the linear variation of the resistance with the velocity. This numerical artefact may lead to an apparent negative viscosity in low-permeable blocks, inducing spurious velocity oscillations. The two-relaxation-times (TRT) LBM may control this effect thanks to free-tunable two-rates combination Λ. Moreover, the Brinkman-force-based BF-TRT schemes may maintain the nondimensional Darcy group and produce viscosity-independent permeability provided that the spatial distribution of Λ is fixed independently of the kinematic viscosity. Such a property is lost not only in the BF-BGK scheme but also by "partial bounce-back" TRT gray models, as shown in this work. Further, we propose a consistent and improved IBF-TRT model which vanishes viscosity correction via simple specific adjusting of the viscous-mode relaxation rate to local permeability value. This prevents the model from velocity fluctuations and, in parallel, improves for effective permeability measurements, from porous channel to multidimensions. The framework of our exact analysis employs a symbolic approach developed for both LBM and FEM in single and stratified, unconfined, and bounded channels. It shows that even with similar bulk discretization, BF, IBF, and FEM may manifest quite different velocity profiles on the coarse grids due to their intrinsic contrasts in the setting of interface continuity and no-slip conditions. While FEM enforces them on the grid vertexes, the LBM prescribes them implicitly. We derive effective LBM continuity conditions and show that the heterogeneous viscosity correction impacts them, a property also shared by FEM for shear stress. But, in contrast with FEM, effective velocity conditions in LBM give rise to slip velocity jumps which depend on (i) neighbor permeability values, (ii) resolution, and (iii) control parameter Λ, ranging its reliable values from Poiseuille bounce-back solution in open flow to zero in Darcy's limit. We suggest an "upscaling" algorithm for Λ, from multilayers to multidimensions in random extremely dispersive samples. Finally, on the positive side for LBM besides its overall versatility, the implicit boundary layers allow for smooth accommodation of the flat discontinuous Darcy profiles, quite deficient in FEM.

Published

2015

16. Stabilizing viscosity contrast effect on miscible displacement in heterogeneous porous media, using lattice Bhatnagar–Gross–Krook simulations

Author

Jerome Martin, Laurent Talon, Dominique Salin, and Nicole Rakotomalala

Subjects

Fluid Flow and Transfer Processes, Physics, Stochastic process, Mechanical Engineering, Gaussian, Numerical analysis, Computational Mechanics, Thermodynamics, Viscous liquid, Condensed Matter Physics, Physics::Fluid Dynamics, Viscous fingering, Viscosity, symbols.namesake, Mechanics of Materials, Lattice (order), symbols, Porous medium

Abstract

We analyze the displacement of a viscous fluid by a miscible more viscous one in heterogeneous porous media. We performed lattice Bhatnagar–Gross–Krook simulations, which were previously successfully applied to the study of the dispersion of a passive tracer in a stochastic heterogeneous porous medium. In the present situation, the flow is stable (no viscous fingering) and leads to an overall Gaussian dispersion, the coefficient of which decreases as the viscosity ratio increases. The results are in reasonable agreement with the stochastic approach of Welty and Gelhar.

Published

2004

17. Fluid displacement between two parallel plates: a non-empirical model displaying change of type from hyperbolic to elliptic equations

Author

Jerome Martin, Dominique Salin, Yanis C. Yortsos, M. Shariati, Laurent Talon, and Nicole Rakotomalala

Subjects

Physics, Mechanical Engineering, Mathematical analysis, Condensed Matter Physics, symbols.namesake, Riemann problem, Hele-Shaw flow, Elliptic partial differential equation, Mechanics of Materials, Piecewise, symbols, Hyperbolic triangle, Displacement (fluid), Hyperbolic partial differential equation, Eigenvalues and eigenvectors

Abstract

We consider miscible displacement between parallel plates in the absence of diffusion, with a concentration-dependent viscosity. By selecting a piecewise viscosity function, this can also be considered as 'three-fluid' flow in the same geometry. Assuming symmetry across the gap and based on the lubrication ('equilibrium') approximation, a description in terms of two quasi-linear hyperbolic equations is obtained. We find that the system is hyperbolic and can be solved analytically, when the mobility profile is monotonic, or when the mobility of the middle phase is smaller than its neighbours. When the mobility of the middle phase is larger, a change of type is displayed, an elliptic region developing in the composition space. Numerical solutions of Riemann problems of the hyperbolic system spanning the elliptic region, with small diffusion added, show good agreement with the analytical outside, but an unstable behaviour inside the elliptic region. In these problems, the elliptic region arises precisely at the displacement front. Crossing the elliptic region requires the solution of essentially an eigenvalue problem of the full higher-dimensional model, obtained here using lattice BGK simulations

Published

2004

18. Strong pinning of propagation fronts in adverse flow

Author

Thomas Gueudré, Awadhesh K. Dubey, Alberto Rosso, Laurent Talon, Laboratoire de Physique Théorique de l'ENS (LPTENS), Université Pierre et Marie Curie - Paris 6 (UPMC)-Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Fluides, automatique, systèmes thermiques (FAST), Université Paris-Sud - Paris 11 (UP11)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Physique Théorique et Modèles Statistiques (LPTMS), Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11), Laboratoire de Physique Théorique de l'ENS [École Normale Supérieure] (LPTENS), Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS.PHYS.PHYS-FLU-DYN]Physics [physics]/Physics [physics]/Fluid Dynamics [physics.flu-dyn], Physics, Stylized fact, Fluid Dynamics (physics.flu-dyn), Front (oceanography), FOS: Physical sciences, Pattern formation, Disordered Systems and Neural Networks (cond-mat.dis-nn), Physics - Fluid Dynamics, Sawtooth wave, Mechanics, Condensed Matter - Disordered Systems and Neural Networks, 01 natural sciences, Pattern selection, 010305 fluids & plasmas, Flow (mathematics), [PHYS.COND.CM-GEN]Physics [physics]/Condensed Matter [cond-mat]/Other [cond-mat.other], 0103 physical sciences, 010306 general physics, Porous medium

Abstract

Reaction fronts evolving in a porous medium exhibit a rich dynamical behaviour. In presence of an adverse flow, experiments show that the front slows down and eventually gets pinned, displaying a particular sawtooth shape. Extensive numerical simulations of the hydrodynamic equations confirm the experimental observations. Here we propose a stylized model, predicting two possible outcomes of the experiments for large adverse flow: either the front develops a sawtooth shape, or it acquires a complicated structure with islands and overhangs. A simple criterion allows to distinguish between the two scenarios and its validity is reproduced by direct hydrodynamical simulations. Our model gives a better understanding of the transition and is relevant in a variety of domains, when the pinning regime is strong and only relies on a small number of sites., 5 pages, 4 figures

Published

2014

19. Blob population dynamics during immiscible two-phase flows in reconstructed porous media

Author

A. G. Yiotis, Dominique Salin, and Laurent Talon

Subjects

Physics::Fluid Dynamics, Physics, Coalescence (physics), education.field_of_study, Population, Nanotechnology, Bond number, Mechanics, Wetting, education, Porosity, Porous medium, Capillary number

Abstract

We study the dynamics of nonwetting liquid blobs during immiscible two-phase flows in stochastically reconstructed porous domains predominantly saturated by a wetting fluid. The flow problem is solved explicitly using a Lattice-Boltzmann model that captures both the bulk phase and interfacial dynamics of the process. We show that the nonwetting blobs undergo a continuous life cycle of dynamic breaking up and coalescence producing two populations of blobs, a mobile and a stranded one, that exchange continuously mass between them. The process reaches a “steady state” when the rates of coalescence and breaking up become equal, and the macroscopic flow variables remain practically constant with time. At steady state, mass partitioning between mobile and immobile populations depends strongly on the applied Bond number Bo and the initial nonwetting phase distributions. Three flow regimes are identified: a single-phase flow Darcy-type regime at low Bo numbers, a non-Darcy two-phaseflow regime at intermediate values of Bo, where the capillary number scales as Ca ∝ Bo 2 , and a Darcy-type two-phase flow regime at higher values of Bo. Our numerical results are found to be in good agreement with recent experimental and theoretical works.

Published

2013

20. Low Reynolds number suspension gravity currents

Author

Laurent Talon, Sandeep Saha, and Dominique Salin

Subjects

Gravity (chemistry), Surface Properties, Biophysics, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, symbols.namesake, Settling, 0103 physical sciences, General Materials Science, 010306 general physics, Suspension (vehicle), Physics, Viscosity, Front (oceanography), Reynolds number, Extracellular Fluid, Surfaces and Interfaces, General Chemistry, Mechanics, Lubrication theory, Gravity current, Models, Chemical, symbols, Hydrodynamics, Particle, Rheology, Biotechnology, Gravitation

Abstract

The extension of a gravity current in a lock-exchange problem, proceeds as square root of time in the viscous-buoyancy phase, where there is a balance between gravitational and viscous forces. In the presence of particles however, this scenario is drastically altered, because sedimentation reduces the motive gravitational force and introduces a finite distance and time at which the gravity current halts. We investigate the spreading of low Reynolds number suspension gravity currents using a novel approach based on the Lattice-Boltzmann (LB) method. The suspension is modeled as a continuous medium with a concentration-dependent viscosity. The settling of particles is simulated using a drift flux function approach that enables us to capture sudden discontinuities in particle concentration that travel as kinematic shock waves. Thereafter a numerical investigation of lock-exchange flows between pure fluids of unequal viscosity, reveals the existence of wall layers which reduce the spreading rate substantially compared to the lubrication theory prediction. In suspension gravity currents, we observe that the settling of particles leads to the formation of two additional fronts: a horizontal front near the top that descends vertically and a sediment layer at the bottom which aggrandises due to deposition of particles. Three phases are identified in the spreading process: the final corresponding to the mutual approach of the two horizontal fronts while the laterally advancing front halts indicating that the suspension current stops even before all the particles have settled. The first two regimes represent a constant and a decreasing spreading rate respectively. Finally we conduct experiments to substantiate the conclusions of our numerical and theoretical investigation.

Published

2013

21. Lock-exchange experiments with an autocatalytic reaction front

Author

Jerome Martin, I. Bou Malham, Dominique Salin, Nolwenn Jarrige, Laurent Talon, and Nicole Rakotomalala

Subjects

Molecular diffusion, Buoyancy, Chemistry, Lattice Boltzmann methods, General Physics and Astronomy, Thermodynamics, engineering.material, Chemical reaction, Molecular physics, Open-channel flow, Gravity current, Viscosity, Front velocity, engineering, Physical and Theoretical Chemistry

Abstract

A viscous lock-exchange gravity current corresponds to the reciprocal exchange of two fluids of different densities in a horizontal channel. The resulting front between the two fluids spreads as the square root of time, with a diffusion coefficient reflecting the buoyancy, viscosity, and geometrical configuration of the current. On the other hand, an autocatalytic reaction front between a reactant and a product may propagate as a solitary wave, namely, at a constant velocity and with a stationary concentration profile, resulting from the balance between molecular diffusion and chemical reaction. In most systems, the fluid left behind the front has a different density leading to a lock-exchange configuration. We revisit, with a chemical reaction, the classical situation of lock-exchange. We present an experimental analysis of buoyancy effects on the shape and the velocity of the iodate arsenous acid autocatalytic reaction fronts, propagating in horizontal rectangular channels and for a wide range of aspect ratios (1/3 to 20) and cylindrical tubes. We do observe stationary-shaped fronts, spanning the height of the cell and propagating along the cell axis. Our data support the contention that the front velocity and its extension are linked to each other and that their variations scale with a single variable involving the diffusion coefficient of the lock-exchange in the absence of chemical reaction. This analysis is supported by results obtained with lattice Bathnagar-Gross-Krook (BGK) simulations Jarrige et al. [Phys. Rev. E 81, 06631 (2010)], in other geometries (like in 2D simulations by Rongy et al. [J. Chem. Phys. 127, 114710 (2007)] and experiments in cylindrical tubes by Pojman et al. [J. Phys. Chem. 95, 1299 (1991)]), and for another chemical reaction Schuszter et al. [Phys. Rev. E 79, 016216 (2009)].

Published

2011

22. Permeability estimates of self-affine fracture faults based on generalization of the bottleneck concept

Author

Alex Hansen, Harold Auradou, and Laurent Talon

Subjects

010504 meteorology & atmospheric sciences, Field (physics), Generalization, Mathematical analysis, 01 natural sciences, Physics::Geophysics, 010305 fluids & plasmas, Permeability (earth sciences), 0103 physical sciences, Fracture (geology), Affine transformation, Cube, Relative permeability, Order of magnitude, 0105 earth and related environmental sciences, Water Science and Technology, Mathematics

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

23. Numerical simulations of a buoyant autocatalytic reaction front in tilted Hele-Shaw cells

Author

Dominique Salin, I. Bou Malham, Laurent Talon, Nicole Rakotomalala, Jerome Martin, and N. Jarrige

Subjects

Physics, Convection, Buoyancy, Eikonal equation, Numerical analysis, Mechanics, engineering.material, Chemical reaction, Physics::Fluid Dynamics, chemistry.chemical_compound, Classical mechanics, chemistry, Lattice (order), engineering, Front velocity, Iodate

Abstract

We present a numerical analysis of solutal buoyancy effects on the shape and the velocity of autocatalytic reaction fronts, propagating in thin tilted rectangular channels. We use two-dimensional (2D) lattice Bathnagar-Gross-Krook (BGK) numerical simulations of gap-averaged equations for the flow and the concentration, namely a Stokes-Darcy equation coupled with an advection-diffusion-reaction equation. We do observe stationary-shaped fronts, spanning the width of the cell and propagating along the cell axis. We show that the model accounts rather well for experiments we performed using an Iodate Arsenous Acid reaction propagating in tilted Hele-Shaw cells, hence validating our 2D modelization of a three-dimensional problem. This modelization is also able to account for results found for another chemical reaction (chlorite tetrathionate) in a horizontal cell. In particular, we show that the shape and the traveling velocity of such fronts are linked with an eikonal equation. Moreover, we show that the front velocity varies nonmonotonically with the tilt of the cell, and nonlinearly with the width of the cell.

Published

2010

24. Measurement of the temperature profile of an exothermic autocatalytic reaction front

Author

Dominique Salin, Jerome Martin, N. Rakotomalala, and Laurent Talon

Subjects

Exothermic reaction, chemistry.chemical_compound, Molecular diffusion, Materials science, chemistry, Infrared, Front velocity, Thermodynamics, Thermal diffusivity, Chemical reaction, Iodate, Order of magnitude

Abstract

Autocatalytic reactions may propagate as solitary waves, namely, at a constant front velocity and with a stationary concentration profile, resulting from a balance between molecular diffusion and chemical reaction. When the reaction is exothermic, a thermal wave is linked to the chemical front. As the thermal diffusivity is nearly two orders of magnitude larger than the molecular one, the temperature profile spreads over length scales (mm) two orders of magnitude larger than the concentration one. Using an infrared camera, we measure the temperature profiles for a chlorite-tetrathionate autocatalytic reaction. The profiles are compared quantitatively to lattice Bhatnagar-Gross-Krook (BGK) numerical simulations. Our analysis also accounts for the lack of observation of the thermal wave for the iodate arsenous acid reaction.

Published

2009

25. Geometrical and Taylor dispersion in a fracture with random obstacles: An experimental study with fluids of different rheologies

Author

Jean-Pierre Hulin, R. Chertcoff, Harold Auradou, Irene Ippolito, Laurent Talon, and Alejandro Boschan

Subjects

010504 meteorology & atmospheric sciences, Scale (ratio), Taylor dispersion, Mathematical analysis, 0207 environmental engineering, 02 engineering and technology, Péclet number, 01 natural sciences, Physics::Fluid Dynamics, symbols.namesake, Classical mechanics, Dispersion (optics), Fracture (geology), symbols, Newtonian fluid, 020701 environmental engineering, Constant (mathematics), Displacement (fluid), 0105 earth and related environmental sciences, Water Science and Technology, Mathematics

Abstract

[1] The miscible displacement of a Newtonian or shear-thinning fluid by another one of same rheological properties has been studied optically in a flat transparent model fracture with a random distribution of identical cylindrical obstacles on one of the walls. At the local scale, the concentration variation on individual pixels satisfies a Gaussian convection-dispersion relation with local transit time (x, y) and dispersivity ld(x, y). The variation of ld with the Peclet number Pe shows that it results from a combination of geometrical and Taylor dispersion, respectively dominant at low and high Pe values. Using shear-thinning solutions instead of a Newtonian fluid enhances the velocity contrasts (and therefore geometrical dispersion) and reduces Taylor dispersion. At the global scale, the front geometry is studied from the isoconcentration lines c = 0.5 (equivalent to lines of constant (x, y) value): beyond a transition travel time, their width in the direction parallel to the flow reaches a constant limit varying linearly with Log(Pe) with a slope increasing with the shear-thinning character of the fluid. These characteristics are compared to previous observations on other model fractures with a self-affine roughness displaying channelization effects.

Published

2008

26. Critical behavior of the banded-unbanded spherulite transition in a mixture of ethylene carbonate with polyacrylonitrile

Author

Laurent Talon, Bram Sadlik, John Bechhoefer, Sébastien Kawka, and Russell Woods

Subjects

Systematic error, chemistry.chemical_compound, Materials science, Transition point, chemistry, Polyacrylonitrile, Thermodynamics, Non-equilibrium thermodynamics, Spherulite (polymer physics), Scaling, Critical exponent, Ethylene carbonate

Abstract

We investigate the transition from unbanded to banded spherulitic growth in mixtures of ethylene carbonate with polyacrylonitrile. By carefully considering systematic errors, we show that the band spacing diverges with a power-law form showing scaling over nearly two decades. We also observe that the bands disorder as the transition point is approached. The critical exponent is nonclassical. One possible explanation is that the nonequilibrium transition is actually weakly first order (subcritical).

Published

2005

27. Crossing the elliptic region in a hyperbolic system with change-of-type behavior arisingin flow between two parallel plates

Author

Dominique Salin, Jerome Martin, Yanis C. Yortsos, Laurent Talon, and Nicole Rakotomalala

Subjects

Elliptic partial differential equation, Hyperbolic function, Mathematical analysis, Ultraparallel theorem, Hyperbolic partial differential equation, Hyperbolic triangle, Angle of parallelism, Inverse hyperbolic function, Hyperbolic equilibrium point, Mathematics

Abstract

Change-of-type behavior from hyperbolic to elliptic is common to quasilinear hyperbolic systems. This issue is addressed here for the particular case of miscible flow of three fluids between two parallel plates. Change of type occurs at the leading edge of the displacement front and reflects the failing of the equilibrium assumption, necessary for the quasilinear hyperbolic formalism, at the front. To cross the elliptic region requires the solution of the full, higher-dimensionality problem, obtained here using lattice gas simulations. For the specific example, it is found that the system self-selects a front structure independent of injection conditions.

Published

2003

28. Lattice BGK simulations of macrodispersion in heterogeneous porous media

Author

Laurent Talon, Nicole Rakotomalala, Dominique Salin, Yannis C. Yortsos, and Jerome Martin

Subjects

Stochastic process, Isotropy, 01 natural sciences, 010305 fluids & plasmas, Correlation function (statistical mechanics), Permeability (earth sciences), Lattice (order), 0103 physical sciences, Vector field, Statistical physics, 010306 general physics, Porous medium, Smoothing, Water Science and Technology, Mathematics

Abstract

[1] We use the extended Darcy's law, which also accounts for the Brinkman correction, to study macrodispersion in a two-dimensional (2-D) porous medium. The former is necessary when permeability changes fast at a relatively small scale, and in general, it is a more complete description of flow in a heterogeneous medium. Lattice-gas methods are ideally suited to simulate such flows. Simulations using a lattice BGK method and a small-fluctuation approach are described for an isotropic, exponentially decaying correlation function of the permeability field. The analytical results contain the additional parameter Kl/λ2 (where Kl and λ are the typical permeability and velocity variation length, respectively), the sensitivity to which was studied. As expected, the contribution of the Brinkman effect is insignificant for typical field values of this parameter, in which case, the classical results are recovered. At larger values, for example, for heterogeneous media of a small correlation length, and possibly in laboratory applications, the Brinkman correction leads to a decrease in macrodispersivity, reflecting the smoothing effect of the Brinkman correction on the velocity field. Nonetheless, for practical values of the parameters, this reduction is no larger than 50% of the classical expression. The small fluctuation theory was found to be in good agreement with the simulations, provided that it was consistently applied (namely, by not mixing first-order with second-order expansions). The results also show that lattice-gas simulations can be usefully employed to study macrodispersion in heterogeneous porous media.

Published

2003

29. Geometry of optimal path hierarchies

Author

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

Subjects

Scale (ratio), Histogram, Path (graph theory), Exponent, Zero (complex analysis), Equipotential, General Physics and Astronomy, Statistical physics, Power law, Energy (signal processing), Mathematics

Abstract

We investigate the hierarchy of optimal paths in a disordered landscape, based on the best path, the second best path and so on in terms of an energy. By plotting each path at a height according to its energy above some zero level, a landscape appears. This landscape is self-affine and controlled by two Hurst exponents: the one controlling the height fluctuations is 1/3 and the one controlling the fluctuations of the equipotential lines in the landscape is 2/3. These two exponents correspond to the exponents controlling energy and shape fluctations in the directed polymer problem. We furthermore find that the density of spanning optimal paths scale as the length of the paths to −2/3 and the histogram of energy differences between consecutive paths scale as a power law in the difference size with exponent −2.5.

Published

2013

30. Phase diagram of sustained wave fronts opposing the flow in disordered porous media

Author

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

Subjects

Materials science, Flow velocity, Percolation, Flow (psychology), Lattice Boltzmann methods, Front (oceanography), General Physics and Astronomy, Upstream (networking), Mechanics, Porous medium, Phase diagram

Abstract

Using lattice Boltzmann simulations, we analyze the different regimes of propagation of an autocatalytic reaction front in heterogenous porous media. The heterogeneities of the porous medium are characterized by the standard deviation of its log-normal distribution of permeability and its correlation length. We focus on the situation where chemical reaction and flow field act in opposite directions. In agreement with previous experiments we observe upstream, downstream fronts as well as static, frozen ones over a range of flow velocity which depends drastically on the heterogeneities of the flow field. The transition between the static regime and the downstream one account for large enough low-velocity zones, whereas the transition from static to upstream regime is found to be given by a kind of percolation path.

Published

2013

31. Miscible viscous fingering in microgravity

Author

Dominique Salin, Jerome Martin, A. Aubertin, Georges Gauthier, and Laurent Talon

Subjects

Fluid Flow and Transfer Processes, Physics, Buoyancy, Mechanical Engineering, Computational Mechanics, Mixing (process engineering), Thermodynamics, engineering.material, Condensed Matter Physics, Instability, Volumetric flow rate, Viscous fingering, Viscosity, Hele-Shaw flow, Mechanics of Materials, engineering, Displacement (fluid)

Abstract

To address the issue of miscible viscous fingering instability in buoyancy free conditions, experiments have been performed under microgravity conditions in parabolic flights. A Hele-Shaw cell, two parallel plates separated by a small gap, has been used with two miscible fluids of viscosity ratio 100 (the injected fluid is the less viscous). The influence of the initial thickness of the pseudointerface between the two fluids has been studied, using flow rates large enough to prevent further mixing during displacement. The selected wavelength, measured on the observed fingering pattern, does not depend on the initial front thickness: It is around three times the gap of the cell, i.e., significantly lower than the value of five, observed on earth. However, the initial thickness does control the displacement length required for the instability to occur. Our results are in reasonable agreement with existing and new numerical simulations.

Published

2009

32. Taylor’s regime of an autocatalytic reaction front in a pulsative periodic flow

Author

Laurent Talon, Nicole Rakotomalala, Jerome Martin, M. Leconte, N. Jarrige, and Dominique Salin

Subjects

Fluid Flow and Transfer Processes, Physics, Molecular diffusion, Advection, Mechanical Engineering, Computational Mechanics, Thermodynamics, Mechanics, Low frequency, Condensed Matter Physics, Hagen–Poiseuille equation, Physics::Fluid Dynamics, Autocatalysis, Hele-Shaw flow, Mechanics of Materials, Front velocity, Vector field, Nonlinear Sciences::Pattern Formation and Solitons

Abstract

Autocatalytic reaction fronts between reacted and unreacted species may propagate as solitary waves, that is, at a constant front velocity and with a stationary concentration profile, which result from a balance between molecular diffusion and chemical reaction. A velocity field in the supporting medium may affect the propagation of such fronts through different phenomena: advection, diffusion enhancement, front shape changes, etc. Here, we report on an experimental study and lattice Bhatnagar–Gross–Krook numerical simulations of the effect of an oscillating flow on the autocatalytic reaction between iodate and arsenous acid in a Hele–Shaw cell. In the low frequency range covered by the experiments, the front behavior is controlled by the flow across the gap and is reproduced with two-dimensional numerical simulations. It is shown that the front velocity oscillates at the frequency of the flow, whereas the front width oscillates at twice that frequency. Moreover, the Taylor regime in the presence of a Poi...

Published

2008

33. Pearl and mushroom instability patterns in two miscible fluids' core annular flows

Author

M. d’Olce, Dominique Salin, Jerome Martin, Laurent Talon, and Nicole Rakotomalala

Subjects

Fluid Flow and Transfer Processes, Physics, Mechanical Engineering, Computational Mechanics, Inner core, Rotational symmetry, Base (geometry), Thermodynamics, Mechanics, Radius, Condensed Matter Physics, Instability, Volumetric flow rate, Pipe flow, Physics::Fluid Dynamics, Core (optical fiber), Mechanics of Materials

Abstract

We report on experiments with two miscible fluids of equal density but different viscosities. The fluids were injected co-currently and concentrically into a cylindrical pipe. The resulting base state is an axisymmetric parallel flow. The ratio of the two fluid flow rates determines the relative amount of the fluids, thus the radius of the inner core fluid. Depending on this radius and the total flow rate, two different and unstable axisymmetric patterns, denoted by mushrooms and pearls, were observed. We delineate the diagram of occurrence of the two patterns as a function of the various parameters.

Published

2008