External Fields

Rouleaux are the cylindrical structures that spontaneously form in our blood when there is no flow and which cause our blood to have a high yield stress. In order to understand the flow of our blood it is therefore of fundamental importance to characterize the build up and break up of these rouleaux. We investigate this effect using our home-build zero-velocity plane shear cell as well as using a fundamental physical-chemical approach to tune interactions.

P. Lettinga

To resolve the microscopic origin of the shear thinning mechanism in polymeric systems, we perform confocal microscopy under flow of F-actin of several tens of microns long. This allows to probe the time-resolved configuration of the polymer chains in full 3D. We find, for example, that shear thinning is accompanied by a layering of the chains in planes perpendicular to the vorticity direction [1].

P. Lettinga

Most soft matter materials cannot be classified as fluids or solids because they possess a dual character: they can have a response that is solid-like or fluid-like, depending on the mechanical deformation. This dual, visco-elastic, character can also be found in an important class of soft matter systems, namely liquid crystals. Liquid crystals can be formed by small ‘colloidal’ platelets, such as clay particles, which all have similar orientation, so that they are in a nematic phase despite of their Brownian motion, which makes them colloidal. We subjected these dispersions of platelets to an oscillating shear field, squeezing the dispersions between two moving plates. By combining this geometry with x-ray scattering, we uncover the structural origin of the transformation between solid and liquid-like behaviour. These new insights might change the view on the origin of visco-elastic behaviour in complex fluids [2, 3].

P. Lettinga

Dispersions of colloidal rods can show very complex behavior under shear flow, depending on the concentration regime. While nematic as well as the dilute suspensions have received a lot of attention, the simple shear thinning response in the semidilute case is surprisingly neither well studied nor understood. In order to investigate the shear flow behavior of rods, filamentous bacteriophages are bio-engineered to create a library of model systems. By using rheo-SANS from two different directions, the 3D particle distributions can be evaluated under shear flow [4].

P. Lettinga

Spatial gradients in the shear rate lead to mass transport, giving rise to non-uniform, banded flow profiles. This instability (the “Shear-gradient Concentration Coupling instability”) is especially relevant for colloidal systems with a yield stress, like glasses and gels. A microscopic theory is developed to explain the origin of the shear-gradient induced mass transport [1].
Experiments are performed on glasses consisting of colloidal rods which reveal various types of non-uniform flow profiles, amongst which are internal fracture, plug flow, and vorticity banding, as well as banded profiles. It is argued that the shear-concentration coupling instability occurs only for colloidal glasses consisting of particles with short-ranged interactions. The shear-banding instability in our soft rod-glasses is due to the classic shear-banding instability, resulting from strong shear thinning [2].

K. Kang, H. Kriegs

Using total internal reflection microscopy (TIRM) we can determine the interaction energy profiles between colloidal particles and flat wall with an unprecedented force resolution. Besides investigating theses energies in equilibrium suspension [2], we investigate how external fields like shear can be used to tune them. Typical examples are depletion forces induced by anisotropic particles, which can be suppressed by aligning the particles in a flow field [3].

P. Lang

We study the effect of solid surfaces on colloidal dynamics by evanescent wave dynamic light scattering. In very dilute suspension of hard spheres, there is a pronounced slowing down of the particles dynamics close to the wall. When particle concentrations increase this effect becomes smaller [4] until it appears to vanish upon approach to the transition from the isotropic to an ordered colloidal state. In suspensions of particles with long ranging charge repulsion [5] the parity of bulk and near wall dynamics can occur at particle concentrations as low as seven per cent.

P. Lang