Julia Yeomans OBE FRS

Shear thinning in dilute polymer solutions.

J Chem Phys 125:19 (2006) 194906

Authors:

JF Ryder, JM Yeomans

Abstract:

We use bead-spring models for a polymer coupled to a solvent described by multiparticle collision dynamics to investigate shear thinning effects in dilute polymer solutions. First, we consider the polymer motion and configuration in a shear flow. For flexible polymer models we find a sharp increase in the polymer radius of gyration and the fluctuations in the radius of gyration at a Weissenberg number approximately 1. We then consider the polymer viscosity and the effect of solvent quality, excluded volume, hydrodynamic coupling between the beads, and finite extensibility of the polymer bonds. We conclude that the excluded volume effect is the major cause of shear thinning in polymer solutions. Comparing the behavior of semiflexible chains, we find that the fluctuations in the radius of gyration are suppressed when compared to the flexible case. The shear thinning is greater and, as the rigidity is increased, the viscosity measurements tend to those for a multibead rod.

Controlling drop size and polydispersity using chemically patterned surfaces

(2006)

Authors:

H Kusumaatmaja, JM Yeomans

Modelling contact angle hysteresis on chemically patterned and superhydrophobic surfaces

(2006)

Authors:

H Kusumaatmaja, JM Yeomans

Lattice Boltzmann algorithm to simulate isotropic-nematic emulsions.

Phys Rev E Stat Nonlin Soft Matter Phys 74:4 Pt 1 (2006) 041708

Authors:

N Sulaiman, D Marenduzzo, JM Yeomans

Abstract:

We present lattice Boltzmann simulations of the dynamical equations of motion of a drop of isotropic fluid in a nematic liquid crystal solvent, both in the absence and in the presence of an electric field. The coupled equations we solve are the Beris-Edward equations for the dynamics of the tensor order parameter describing the nematic solvent, the Cahn-Hilliard equation for the concentration evolution, and the Navier-Stokes equations for the determination of the instantaneous velocity field. We implement the lattice Boltzmann algorithm to ensure that spurious velocities are close to zero in equilibrium. We first study the effects of the liquid crystal elastic constant, K, anchoring strength, W, and surface tension, sigma, on the shape of the droplet and on the director field texture in equilibrium. We then consider how the drop behaves as the director field is switched by an applied electric field. We also show that the algorithm allows us to follow the motion of a drop of isotropic fluid placed in a liquid crystal cell with a tilted director field at the boundaries.

Stabilising the Blue Phases

(2006)

Authors:

GP Alexander, JM Yeomans