Probing microsecond dynamics of disperse nanoparticles at oil-water interfaces using nanometer localization precision total-internal-reflection dark-field microscopy

TL;DR

This study uses high-speed, high-resolution microscopy to investigate nanometer-scale particle dynamics at oil-water interfaces, revealing size-dependent adsorption barriers and multiple stable immersion states influenced by surfactants.

Contribution

The paper introduces a novel TIR-DF microscopy technique with nanometer spatial and microsecond temporal resolution to study nanoparticle interfacial dynamics.

Findings

Surfactants make adsorption reversible and reverse size-diffusivity trends.

Larger particles exhibit fewer adsorption events, indicating size-dependent barriers.

Particles show multiple stable immersion states over short timescales.

Abstract

Particles at fluid-fluid interfaces have a wide range of important applications in industry, technology and science. Questions remain about what governs adsorption dynamics and inter-particle interactions, and how mixtures -- both of different-sized particles, and particles and surfactants -- behave. I probe the dynamics of nanoparticles at oil-water interfaces using high-speed total-internal-reflection dark-field (TIR-DF) microscopy, comparing gold particles of diameters 20, 40 and 80 nanometers, and investigating the effect of an added surfactant. I built a TIR-DF microscope with a spatiotemporal resolution of up to 1 nanometer at 20 microseconds, and characterized the particle motion by direct imaging for the diffusive motion within the interfacial plane, and attenuation of light scattering and in-plane motion for out-of-plane motion. The addition of surfactant was found to qualitatively alter the interaction between the particles and the interface: Adsorptions became reversible and the size trend in diffusivity was reversed (larger particles diffused faster than smaller ones). The combination of this and the rarity of adsorption events of larger particles leads me to propose size-dependent barriers to adsorption at surfactant interfaces. In addition, at surfactant interfaces, many particles' diffusive behavior changed over the course of a trajectory, indicating several different immersion states that are stable on the experimental timescale (approximately 1 second). This study shows that there remain qualitatively new dynamics of nanoparticles at oil-water interfaces to be explored. These dynamics can only be resolved at a high spatial resolution, and many of them only at high imaging speed, underlining the importance of novel imaging approaches probing the barriers of achievable spatiotemporal resolution.