46 research outputs found
Interface deformations affect the orientation transition of magnetic ellipsoidal particles adsorbed at fluid-fluid interfaces
Manufacturing new soft materials with specific optical, mechanical and
magnetic properties is a significant challenge. Assembling and manipulating
colloidal particles at fluid interfaces is a promising way to make such
materials. We use lattice-Boltzmann simulations to investigate the response of
magnetic ellipsoidal particles adsorbed at liquid-liquid interfaces to external
magnetic fields. We provide further evidence for the first-order orientation
phase transition predicted by Bresme and Faraudo [Journal of Physics: Condensed
Matter 19 (2007), 375110]. We show that capillary interface deformations around
the ellipsoidal particle significantly affect the tilt-angle of the particle
for a given dipole-field strength, altering the properties of the orientation
transition. We propose scaling laws governing this transition, and suggest how
to use these deformations to facilitate particle assembly at fluid-fluid
interfaces.Comment: 7 pages, 8 figure
Physical Methods for the Preparation of Hybrid Nanocomposite Polymer Latex Particles
In this chapter, we will highlight conceptual physical approaches towards the fabrication of nanocomposite polymer latexes in which each individual latex particle contains one or more "hard" nanoparticles, such as clays, silicates, titanates, or other metal(oxides). By "physical approaches" we mean that the "hard" nanoparticles are added as pre-existing entities, and are not synthesized in situ as part of the nanocomposite polymer latex fabrication process. We will narrow our discussion to focus on physical methods that rely on the assembly of nanoparticles onto the latex particles after the latex particles have been formed, or its reciprocal analogue, the adhesion of polymer onto an inorganic nanoparticle. First, will discuss the phenomenon of heterocoagulation and its various driving forces, such as electrostatic interactions, the hydrophobic effect, and secondary molecular interactions. We will then address methods that involve assembly of nanoparticles onto or around the more liquid precursors (i.e., swollen/growing latex particles or monomer droplets). We will focus on the phenomenon of Pickering stabilization. We will then discuss features of particle interaction with soft interfaces, and see how the adhesion of particles onto emulsion droplets can be applied in suspension, miniemulsion, and emulsion polymerization. Finally, we will very briefly mention some interesting methods that make use of interface-driven templating for making well-defined assembled clusters and supracolloidal structures