Julia Yeomans OBE FRS

Activity pulses induce spontaneous flow reversals in viscoelastic environments

Authors:

Emmanuel LC VI M Plan, Julia M Yeomans, Amin Doostmohammadi

Controlling collective rotational patterns of magnetic rotors

Nature Communications Nature Research (part of Springer Nature)

Authors:

J Yeomans, D Matsunaga, F Meng, R Golestanian

Driven spheres, ellipsoids and rods in explicitly modeled polymer solutions.

Journal of physics. Condensed matter : an Institute of Physics journal

Authors:

Andreas Zöttl, Julia M Yeomans

Abstract:

Understanding the transport of driven nano- and micro-particles in complex fluids is of relevance for many biological and technological applications. Here we perform hydrodynamic multiparticle collision dynamics simulations of spherical and elongated particles driven through polymeric fluids containing different concentrations of polymers. We determine the mean particle velocities which are larger than expected from Stokes law for all particle shapes and polymer densities. Furthermore we measure the fluid flow fields and local polymer density and polymer conformation around the particles. We find that polymer-depleted regions close to the particles are responsible for an apparent tangential slip velocity which accounts for the measured flow fields and transport velocities. A simple two-layer fluid model gives a good match to the simulation results.

Nature of active forces in tissues: how contractile cells can form extensile monolayers

Authors:

Lakshmi Balasubramaniam, Amin Doostmohammadi, Thuan Beng Saw, Gautham Hari Narayana Sankara Narayana, Romain Mueller, Tien Dang, Minnah Thomas, Shafali Gupta, Surabhi Sonam, Alpha S Yap, Yusuke Toyama, René-Marc Mège, Julia Yeomans, Benoît Ladoux

Reconfigurable Flows and Defect Landscape of Confined Active Nematics

Communications Physics Nature Research (part of Springer Nature)

Authors:

Jérôme Hardoüin, Rian Hughes, Amin Doostmohammadi, Justine Laurent, Teresa Lopez-Leon, Julia M Yeomans, Jordi Ignés-Mullol, Francesc Sagués

Abstract:

Using novel micro-printing techniques, we develop a versatile experimental setup that allows us to study how lateral confinement tames the active flows and defect properties of the microtubule/kinesin active nematic system. We demonstrate that the active length scale that determines the self-organization of this system in unconstrained geometries loses its relevance under strong lateral confinement. Dramatic transitions are observed from chaotic to vortex lattices and defect-free unidirectional flows. Defects, which determine the active flow behavior, are created and annihilated on the channel walls rather than in the bulk, and acquire a strong orientational order in narrow channels. Their nucleation is governed by an instability whose wavelength is effectively screened by the channel width. All these results are recovered in simulations, and the comparison highlights the role of boundary conditions.