Rotational Dynamics of Discoid Colloidal Particles in Attractive Quasi-Two-Dimensional Plastic Crystals

Plastic crystals formed from anisotropic molecules or particles are an important state of matter characterized by the presence of long-range positional order and the lack of long-range orientational order. The rotational motion of molecules or particles in plastic crystals is the most attractive characteristic of the system. Here the rotational dynamics of the discoid particles in quasi-two-dimensional colloidal plastic crystals stabilized via depletion interactions are quantitatively studied using time-resolved confocal microscopy. The measured probability distribution of particle orientation reveals the existence of a strong coupling between the lattice symmetry and particle rotation, resulting in anisotropic rotational dynamics modes resembling the underlying hexagonal crystalline symmetry. Furthermore, the orientational distribution function provides information about the potential surface of rotational dynamics. The observed slow rotational diffusion can be attributed to the presence of orientational minima and potential barriers on the potential surface. Our findings with a real experimental system provide important insights into the role of attraction in the phase behaviors of plastic crystals.

Automated summary

This study quantitatively investigates the rotational dynamics of discoid particles in quasi-two-dimensional colloidal plastic crystals stabilized via depletion interactions using time-resolved confocal microscopy. The results reveal a strong coupling between lattice symmetry and particle rotation, resulting in anisotropic rotational dynamics resembling the underlying hexagonal crystalline symmetry. The observed slow rotational diffusion is attributed to orientational minima and potential barriers on the potential surface. These findings provide important insights into the role of attraction in the phase behaviors of plastic crystals.