Julia Yeomans OBE FRS

Lattice Boltzmann simulations of lamellar and droplet phases

PHYSICAL REVIEW E 58:1 (1998) 480-485

Authors:

G Gonnella, E Orlandini, JM Yeomans

Breakdown of scale-invariance in the coarsening of phase-separating binary fluids

(1997)

Authors:

Alexander J Wagner, JM Yeomans

Effect of shear on droplets in a binary mixture

(1997)

Authors:

Alexander J Wagner, JM Yeomans

Effect of shear on droplets in a binary mixture

INT J MOD PHYS C 8:4 (1997) 773-782

Authors:

AJ Wagner, JM Yeomans

Abstract:

In this article we use a lattice-Boltzmann simulation to examine the effects of shear flow on an equilibrium droplet in a phase separated binary mixture. We find that large drops break up as the shear is increased but small drops dissolve. We also show how the tip-streaming, observed for deformed drops, leads to a state of dynamic equilibrium.

Lattice-Boltzmann simulations of complex fluids

INT J MOD PHYS C 8:4 (1997) 783-792

Authors:

G Gonnella, E Orlandini, JM Yeomans

Abstract:

We show that by including thermodynamic functions derived from a chosen free energy in a lattice-Boltzmann simulation of fluid how it is possible to ensure that the fluid relaxes to a well-defined equlilibrium corresponding to the minimum of the input free energy. Two examples are given of phase separation in a binary fluid: bulk two-phase coexistence and a lamellar phase stabilised by a competition between negative surface tension and positive curvature energy. The lattice-Boltzmann framework simulates the Navier-Stokes equations of fluid flow and hence allows investigation of the effects of hydrodynamics on the kinetics of phase separation and on the rheology of the ordered structures.