Who wins the race near the interface? Stratification of colloids, nano-surfactants, and others

The diffusion of colloids, nanoparticles, and small molecules near the gas-liquid interface presents interesting multiphase transport phenomena and unique opportunities for understanding interactions near the surface and interface. Stratification happens when different species preside over the interfaces in the final dried coating structure. Understanding the principles of stratification can lead to emerging technologies for materials' fabrication and has the potential to unlock innovative industrial solutions, such as smart coatings and drug formulations for controlled release. However, stratification can be perplexing and unpredictable. It may involve a complicated interplay between particles and interfaces. The surface chemistry and solution conditions are critical in determining the race of particles near the interface. Current theory and simulation cannot fully explain the observations in some experiments, especially the newly developed stratification of nano-surfactants. Here, we summarize the efforts in the experimental work, theory, and simulation of stratification, with an emphasis on bridging the knowledge gap between our understanding of surface adsorption and bulk diffusion. We will also propose new mechanisms of stratification based on recent observations of nano-surfactant stratification. More importantly, the discussions here will lay the groundwork for future studies beyond stratification and nano-surfactants. The results will lead to the fundamental understanding of nanoparticle interactions and transport near interfaces, which can profoundly impact many other research fields, including nanocomposites, self-assembly, colloidal stability, and nanomedicine. Published under an exclusive license by AIP Publishing.

Automated summary

The diffusion of colloids, nanoparticles, and small molecules near the gas-liquid interface presents interesting multiphase transport phenomena and unique opportunities for understanding interactions near the surface and interface. However, stratification can be perplexing and unpredictable. Current theory and simulation cannot fully explain the observations in some experiments, especially the newly developed stratification of nano-surfactants. This article summarizes the efforts in experimental work, theory, and simulation of stratification, with an emphasis on bridging the knowledge gap between our understanding of surface adsorption and bulk diffusion.