posted on 2019-08-02, 16:35authored byA. Mikkelsen, Z. Rozynek
Similar to the human
skin, a monolayer of packed particles capillary bound to a liquid
interface wrinkles when subjected to compressive stress. The induced
wrinkles absorb the applied stress and do not disappear unless the
stress is removed. Experimental and theoretical investigations of
wrinkle formation typically concern flat particle monolayers subjected
to uniaxial stress. In this work, we extend the results on wrinkling
of particle-covered interfaces to the investigation of mechanical
properties of particle films on a curved interface, that is, we study
particle shells formed on droplets and subjected to hoop stress. Opposed
to flat particle layers where liquid buoyancy alone acts as the effective
stiffness, the mechanical properties of particle layers on small droplets
are also affected by the surface curvature. We show here that this
leads to formation of wrinkles with different characteristic wavelengths
compared to those found at flat interfaces. Our experimental results
also reveal that the wrinkle wavelength of particle shells is proportional
to the square root of particle size and the size of the droplets on
which the shells are formed. Wrinkling of particle layers composed
of microparticles with diameters ranging from around 1–100
μm was induced using a novel approach combining electrodeformation
and electrohydrodynamic flows. We demonstrate that our contactless
approach for studying the mechanical properties of particle shells
enables estimation of elasticity, particle film thickness, and bending
stiffness of particle shells. The proposed approach is insensitive
to both particle coverage and electric field strength. In addition,
it enables manipulation of particle packing that is intimately linked
with formation of wrinkling patterns. With a wide range of applications
depending on accurate mechanical properties (e.g., drug-delivery capsules
to self-healing materials), this work provides a valuable method to
characterize the mechanical properties of shells and tailor their
surface properties (i.e., permeability and roughness).