Collective dynamics of flowing colloids during pore clogging.

Based on direct numerical simulations of the coupled motion of particles and fluid, this study analyzes the collective hydrodynamic and colloidal effects of flowing microparticles during the formation of different 3D clogging patterns at a pore entrance. Simulations of flowing suspensions through a pore with various simulation conditions show that particle concentration and surface interactions play a major role in the occurrence of the bridging phenomenon (simultaneous adhesion of many particles). In the absence of DLVO repulsive forces, plugging is characterized by the temporal reduction of the bulk permeability when increasing the volume fraction of the flowing suspension up to 20%. Under these conditions, different structures of particle aggregates (from cluster to cake plug) are formed at the pore entrance yielding different evolution rates of hydrodynamic resistance to the flow. Taking into account DLVO repulsive forces in simulations for a particle concentration equal to 10%, we observe the transition from dendritic structures (for low repulsion) to dense aggregates (for high repulsion). At high DLVO repulsive forces, the scenario of pore clogging is controlled by the collective behavior of many interacting particles. It leads to the formation of a jamming phase (Wigner glass phase) with transient clusters of interacting particles at the pore entrance. The network of jammed particles collapses when the force chains among the particles are overcome by the flow stress. The build-up and the collapse of the jammed phase at the pore entrance induce temporal permeability fluctuations. According to the relative magnitude of particle-particle and particle-wall interactions, when the jammed phase is disorganized by the flow, the residual force in the network can accelerate particles and lead to particle adhesion at the wall inducing a pore blockage and a rapid reduction of the bulk permeability.

[1]  W. Kegel,et al.  A qualitative confocal microscopy study on a range of colloidal processes by simulating microgravity conditions through slow rotations , 2012 .

[2]  Nouhad Abidine,et al.  Low fouling conditions in dead-end filtration: Evidence for a critical filtered volume and interpretation using critical osmotic pressure , 2005 .

[3]  A. Zydney,et al.  Effect of electrostatic, hydrodynamic, and Brownian forces on particle trajectories and sieving in normal flow filtration. , 2004, Journal of colloid and interface science.

[4]  Alkiviades C. Payatakes,et al.  Dendritic deposition of aerosols by convective Brownian diffusion for small, intermediate and high particle Knudsen numbers , 1980 .

[5]  Liu,et al.  Force Distributions near Jamming and Glass Transitions. , 2001, Physical review letters.

[6]  Jean-Pierre Minier,et al.  Towards a description of particulate fouling: from single particle deposition to clogging. , 2012, Advances in colloid and interface science.

[7]  M. Meireles,et al.  Colloidal surface interactions and membrane fouling: investigations at pore scale. , 2011, Advances in colloid and interface science.

[8]  M. Maxey,et al.  Force-coupling method for particulate two-phase flow: stokes flow , 2003 .

[9]  Martin R. Maxey,et al.  Numerical simulations of random suspensions at finite Reynolds numbers , 2003 .

[10]  H. Cummins,et al.  Hydrodynamic and interparticle potential effects on aggregation of colloidal particles. , 2012, Journal of colloid and interface science.

[11]  H. S. Fogler,et al.  Plugging by hydrodynamic bridging during flow of stable colloidal particles within cylindrical pores , 1999, Journal of Fluid Mechanics.

[12]  W. R. Schowalter,et al.  The effect of Brownian diffusion on shear-induced coagulation of colloidal dispersions , 1983, Journal of Fluid Mechanics.

[13]  P. Aimar,et al.  Coagulation of colloids in a boundary layer during cross-flow filtration , 1998 .

[14]  Olivier Simonin,et al.  Dynamics of bidisperse suspensions under Stokes flows: Linear shear flow and sedimentation , 2006 .

[15]  B. Stoeber,et al.  Deposition of particles from polydisperse suspensions in microfluidic systems , 2010 .

[16]  Pierre Aimar,et al.  Model for colloidal fouling of membranes , 1995 .

[17]  R. Lenormand,et al.  Particle accumulation at the surface of a filter , 1986 .

[18]  Eric Climent,et al.  Experimental investigation of pore clogging by microparticles: Evidence for a critical flux density of particle yielding arches and deposits , 2012 .

[19]  Martin R. Maxey,et al.  Simulation of concentrated suspensions using the force-coupling method , 2010, J. Comput. Phys..

[20]  Andrew L. Zydney,et al.  Particle¿particle interactions during normal flow filtration: Model simulations , 2005 .

[21]  P. Levitz,et al.  Liquid-solid transition of Laponite suspensions at very low ionic strength: Long-range electrostatic stabilisation of anisotropic colloids , 2000 .

[22]  P. Schmitz,et al.  Particle aggregation at the membrane surface in crossflow microfiltration , 1993 .

[23]  W. Kegel,et al.  Direct observation of dynamical heterogeneities in colloidal hard-sphere suspensions , 2000, Science.

[24]  R. V. D. Sman,et al.  Suspension flow modelling in particle migration and microfiltration , 2010 .

[25]  E. Climent,et al.  Numerical investigation of channel blockage by flowing microparticles , 2014 .

[26]  H. N. Unni,et al.  Brownian dynamics simulation and experimental study of colloidal particle deposition in a microchannel flow. , 2005, Journal of colloid and interface science.

[27]  Sarah L. Dance,et al.  Incorporation of lubrication effects into the force-coupling method for particulate two-phase flow , 2003 .

[28]  A. Acrivos,et al.  Microstructure and velocity fluctuations in sheared suspensions , 2003, Journal of Fluid Mechanics.

[29]  M. Maxey,et al.  Localized force representations for particles sedimenting in Stokes flow , 2001 .

[30]  M. Maxey,et al.  Experimental verification of the force coupling method for particulate flows , 2002 .

[31]  A. Zydney,et al.  A Combined Pore Blockage and Cake Filtration Model for Protein Fouling during Microfiltration. , 2000, Journal of colloid and interface science.

[32]  A. Merlin,et al.  Microfluidic-assisted growth of colloidal crystals† , 2012 .

[33]  Howard A Stone,et al.  Mechanism for clogging of microchannels. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[34]  E. Nazockdast,et al.  Effect of repulsive interactions on structure and rheology of sheared colloidal dispersions , 2012 .

[35]  I. W. Cumming,et al.  Modelling of dead-end microfiltration with pore blocking and cake formation , 2002 .