Julia Yeomans OBE FRS

Hydrodynamics and rheology of active liquid crystals: A numerical investigation

PHYSICAL REVIEW LETTERS 98:11 (2007) ARTN 118102

Authors:

D Marenduzzo, E Orlandini, JM Yeomans

Modeling microscopic swimmers at low Reynolds number

JOURNAL OF CHEMICAL PHYSICS 126:6 (2007) ARTN 064703

Authors:

David J Earl, CM Pooley, JF Ryder, Irene Bredberg, JM Yeomans

Modelling drop dynamics on patterned surfaces

BULLETIN OF THE POLISH ACADEMY OF SCIENCES-TECHNICAL SCIENCES 55:2 (2007) 203-210

Authors:

JM Yeomans, H Kusumaatmaja

Steady-state hydrodynamic instabilities of active liquid crystals: Hybrid lattice Boltzmann simulations

PHYSICAL REVIEW E 76:3 (2007) ARTN 031921

Authors:

D Marenduzzo, E Orlandini, ME Cates, JM Yeomans

Viscoelastic flows of cholesteric liquid crystals

MOL CRYST LIQ CRYST 465 (2007) 1-14

Authors:

E Orlandini, D Marenduzzo, JM Yeomans

Abstract:

We numerically solve the hydrodynamic equations of motion for a cholesteric liquid crystal under an imposed Poiseuille flow, by means of lattice Boltzmann simulations. The elasticity of the cholesteric helix couples to the external flow to give rise to a highly viscoelastic flow. This is a technically difficult problem for standard flow solvers due to its fully two-dimensional nature. We consider a helix with axis parallel to the boundaries, and at the same time to either the primary flow or the vorticity direction (we identify these two flow modes as permeation and vorticity mode respectively). We quantify the large difference found in the steady state director and velocity profiles, and in the apparent viscosities obtained in the two cases.