posted on 2023-11-14, 15:36authored byXi Li, Kara L. Maki, Michael J. Schertzer
This work investigates the deposition patterns left by
evaporating
particle-laden droplets on heterogeneous surfaces with spatially varying
wettability. Spatial differences in receding contact angles give rise
to scalloped-shaped contact lines. During evaporation, the contact
line recedes in one location and remains pinned in another. This nonuniform
contact line recession results in particle self-assembly above areas
where the contact line remains pinned but not where it recedes. This
behavior is fairly robust across a variety of particle sizes, concentrations,
and device geometries. We hypothesize that particle self-assembly
in these cases is due to the competition between particle diffusion
and evaporative-driven advective flow. Diffusion appears to be more
pronounced in regions where the contact line recedes, while advection
appears to be more pronounced near the pinned portion of the contact
line. As such, particles appear to diffuse away from receding areas
and toward pinned areas, where advection transports them to the contact
line. The distribution of particle deposition above the pinned regions
was influenced by the particle size and the concentration of particles
in the droplet. Similar to homogeneous surfaces, deposition was more
prevalent at the pinned portion of the contact line for smaller particles
and lower concentrations and more uniformly distributed across the
entire pinned region for larger particles and higher concentrations.
A better understanding of this process may be beneficial in a wide
variety of particle separation applications, such as printing, cell
patterning, biosensing, and anti-icing.