Effect of particle anisotropy on the thermodynamics and kinetics of ordering transitions in hard faceted particles

Monte Carlo simulations were used to study the influence of particle aspect ratio on the kinetics and phase behavior of hard gyrobifastigia (GBF). First, the formation of a highly anisotropic nucleus shape in the isotropic-to-crystal transition in regular GBF is explained by the differences in interfacial free energies of various crystal planes and the nucleus geometry predicted by the Wulff construction. GBF-related shapes with various aspect ratios were then studied, mapping their equations of state, determining phase coexistence conditions via interfacial pinning, and computing nucleation free-energy barriers via umbrella sampling using suitable order parameters. Our simulations reveal a reduction of the kinetic barrier for isotropic-crystal transition upon an increase in aspect ratio, and that for highly oblate and prolate aspect ratios, an intermediate nematic phase is stabilized. Our results and observations also support two conjectures for the formation of the crystalline state from the isotropic phase: that low phase free energies at the ordering phase transition correlate with low transition barriers and that the emergence of a mesophase provides a steppingstone that expedites crystallization.

Automated summary

Monte Carlo simulations were used to investigate the effects of particle aspect ratio on the kinetics and phase behavior of hard gyrobifastigia (GBF). The results showed that an increase in aspect ratio reduces the kinetic barrier for the isotropic-crystal transition and stabilizes an intermediate nematic phase for highly oblate and prolate ratios. The study also supported two conjectures for crystallization: low phase free energies at the ordering phase transition correlate with low transition barriers, and the emergence of a mesophase expedites crystallization.