Nanoparticles at fluid interfaces: Exploiting capping ligands to control adsorption, stability and dynamics

Nanoparticle self-assembly at fluid–fluid interfaces has been traditionally exploited in emulsification, encapsulation and oil recovery, and more recently in emerging applications including functional nanomaterials and biphasic catalysis. We provide a review of the literature focusing on the open challenges that still hamper the broader applicability of this potentially transformative technology, and we outline strategies to achieve improved control over interfacial self-assembly of nanoparticles. First, we discuss means to promote spontaneous adsorption by tuning the interfacial energies of the nanoparticles with the fluids using capping ligands, and the occurrence of energy barriers. We then examine the interactions between interfacial nanoparticles and how they affect the formation of equilibrium interfacial suspensions versus non-equilibrium two-dimensional phases, such as weakly attractive glasses and gels. Important differences with colloidal interactions in a bulk suspension arise due to the discontinuity in solvent properties at the interface. For instance, ligand brushes rearrange in asymmetric configurations, and thus play a significant role in determining interparticle interactions. Finally, we briefly discuss the link between interfacial microstructure and the dynamic response of particle-laden interfaces, including interfacial rheology and the fate of nanoparticle monolayers upon out-of-plane deformation.

Graphical abstractFigure optionsDownload full-size imageDownload high-quality image (202 K)Download as PowerPoint slideHighlights► Outlines criteria to engineer nanoparticle monolayers at fluid interfaces. ► Highlights role of ligands in nanoparticle monolayer thermodynamics and mechanics. ► Spontaneous adsorption of nanoparticles can be promoted with capping ligands. ► Criteria for stability of an interfacial suspension are more stringent than in bulk. ► Ligand-mediated interactions can be tuned to promote either desorption or buckling.