The origin of the viscoelastic behavior that many nanoparticles display during diffusive motion is unknown. Such dynamics are difficult to record without sophisticated methods that combine a suitable observation window of motion in time with high image resolution. Herein, we study and describe the diffusion of two types of particles in the form of emulsion droplets in situ via liquid phase TEM. For both, the observed particle motion in solution is anomalous (non-Brownian) and is either sub- or super-diffusive. Fractional Brownian motion (fBm) and random walks on fractals (RWF) are the two potential mechanisms. It can be challenging to differentiate these since they may have the same position or velocity autocorrelation function, but they diverge in the average number of sites visited, which is connected to the fractal dimension of the walk. We conclude that droplet-surface interactions and electron beam fluence create a fractal energy landscape yielding peculiar dynamics.
Vratsanos, M.A., Bakalis, E., Park, C., Zerbetto, F., Gianneschi, N.C. (2026). Liquid Phase TEM of Diffusing Emulsion Droplets. SMALL, e12006, 1-11 [10.1002/smll.202512006].
Liquid Phase TEM of Diffusing Emulsion Droplets
Bakalis, Evangelos;Zerbetto, Francesco;
2026
Abstract
The origin of the viscoelastic behavior that many nanoparticles display during diffusive motion is unknown. Such dynamics are difficult to record without sophisticated methods that combine a suitable observation window of motion in time with high image resolution. Herein, we study and describe the diffusion of two types of particles in the form of emulsion droplets in situ via liquid phase TEM. For both, the observed particle motion in solution is anomalous (non-Brownian) and is either sub- or super-diffusive. Fractional Brownian motion (fBm) and random walks on fractals (RWF) are the two potential mechanisms. It can be challenging to differentiate these since they may have the same position or velocity autocorrelation function, but they diverge in the average number of sites visited, which is connected to the fractal dimension of the walk. We conclude that droplet-surface interactions and electron beam fluence create a fractal energy landscape yielding peculiar dynamics.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
