Julia Yeomans OBE FRS

Velocity Correlations in an Active Nematic

ArXiv 1302.6732 (2013)

Authors:

Sumesh P Thampi, Ramin Golestanian, Julia M Yeomans

Abstract:

The flow properties of a continuum model for an active nematic is studied and compared with recent experiments on suspensions of microtubule bundles and molecular motors. The velocity correlation length is found to be independent of the strength of the activity while the characteristic velocity scale increases monotonically as the activity is increased, both in agreement with the experimental observations. We interpret our results in terms of the creation and annihilation dynamics of a gas of topological defects.

Velocity Correlations in an Active Nematic

(2013)

Authors:

Sumesh P Thampi, Ramin Golestanian, Julia M Yeomans

Modelling unidirectional liquid spreading on slanted microposts

(2013)

Authors:

Andrea Cavalli, Matthew L Blow, Julia M Yeomans

Liquid crystal microfluidics for tunable flow shaping

Physical Review Letters 110:4 (2013)

Authors:

A Sengupta, U Tkalec, M Ravnik, JM Yeomans, C Bahr, S Herminghaus

Abstract:

We explore the flow of a nematic liquid crystal in microfluidic channels with a rectangular cross section through experiments and numerical modeling. The flow profile and the liquid crystal orientational profile show three distinct regimes of weak, medium, and strong flow as the driving pressure is varied. These are identified by comparing polarizing optical microscopy experiments and numerical solutions of the nematofluidic equations of motion. The relative stability of the regimes is related to the de Gennes characteristic shear-flow lengths e1 and e2, together with the channel's aspect ratio w/d. Finally, we show that the liquid crystalline microfluidic flow can be fully steered from left to right of a simple microchannel by applying transverse temperature gradients. © 2013 American Physical Society.

Anisotropic wetting and de-wetting of drops on substrates patterned with polygonal posts

Soft Matter 9:3 (2013) 674-683

Authors:

RJ Vrancken, ML Blow, H Kusumaatmaja, K Hermans, AM Prenen, CWM Bastiaansen, DJ Broer, JM Yeomans

Abstract:

We present results showing how water drops, produced by ink-jet printing, spread on surfaces patterned with lattices of diamond or triangular posts. Considering post widths typically ∼7 μm and lattice spacings between 15 and 40 μm, we observe drop shapes with 3, 4 and 6-fold symmetry, depending on both the symmetry of the lattice and the shape of the posts. This is a result of the different mechanisms of interface pinning and depinning which depend on the direction of the contact line motion with respect to the post shape. Lattice Boltzmann simulations are used to describe these mechanisms in detail for triangular posts. We also follow the motion of the contact line as the drops evaporate showing that they tend to return to their original shape. To explain this we show that the easy direction for movement is the same for spreading and drying drops. We compare the behaviour of small drops with that of larger drops created by jetting several drops at the same position. We find that the contact line motion is unexpectedly insensitive to drop volume, even when a spherical cap of fluid forms above the posts. The findings are relevant to micro-fluidic applications and to the control of drop shapes in ink-jet printing. © 2013 The Royal Society of Chemistry.