2017
DOI: 10.1017/jfm.2017.789
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Non-equilibrium pair interactions in colloidal dispersions

Abstract: We study non-equilibrium pair interactions between microscopic particles moving through a model shear-thinning fluid. Prior efforts to model pair interactions in non-Newtonian fluids have largely focused on constitutive models derived from polymer-chain kinetic theories focusing on conformational degrees of freedom, but neglecting the details of microstructural evolution beyond a single polymer length scale. To elucidate the role of strong structural distortion in mediating pair interactions in Brownian suspen… Show more

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Cited by 9 publications
(5 citation statements)
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“…Many-particle hydrodynamic interactions are dominant when these radii are of the same order. According to Brady and coworkers, the viscosity of the solvent can be considered unaffected by the flow around the particles for [43,44]. This ratio is rather common for the particles of interest, see for instance, the size of the core, R h , vs. the thickness of the shell, R th − R h , in the core-shell particles in [45,46].…”
Section: Extended Brownian Dynamics Modelmentioning
confidence: 99%
“…Many-particle hydrodynamic interactions are dominant when these radii are of the same order. According to Brady and coworkers, the viscosity of the solvent can be considered unaffected by the flow around the particles for [43,44]. This ratio is rather common for the particles of interest, see for instance, the size of the core, R h , vs. the thickness of the shell, R th − R h , in the core-shell particles in [45,46].…”
Section: Extended Brownian Dynamics Modelmentioning
confidence: 99%
“…When several TPs are present, each of them will perturb the distribution of the environment particles in its vicinity and in order to minimise the micro-structural changes in the environment and to reduce the dissipation, they will start to move collectively. Stochastic pairing of two biased TPs has been observed in simulations in a model of a two-dimensional lattice gas [176], in experiments in colloidal suspensions [177,178], and also theoretically predicted for the relative motion of two TPs in a nearly-critical fluid mixture, due to emerging critical Casimir forces [179]. Formation of string-like clusters of TPs, or "trains" of TPs, which reveals an emerging effective attraction between them has been evidenced for situations with a small concentration of TPs [180][181][182].…”
Section: Density Profiles Of the Environment Particlesmentioning
confidence: 95%
“…Assuming semidilute polymers, the interparticle potential V = V brush + V HS is a sum of the entropic penalty of chain stretching and hard-core repulsion between monomers (see ESI † for functional forms). Normally, the translational motion of the colloids would also produce an advective particle flux contribution, vre x , which scales with the approach velocity, v. [19][20][21][22] Because our model aims to capture the transient relaxation after colloidal motion has ceased (v = 0 for t Z 0), we choose to set an initial, nonequilibrated concentration field to represent the state of monomers at t = 0 (see ESI †). Eqn (1) is numerically evaluated using the finite element software package FreeFEM++ 23 for an arbitrarily-large 3-dimensional volume which includes both colloidal particles and the two polymer brush domains.…”
Section: Smoluchowski Theorymentioning
confidence: 99%