Kinetics of Crystallization and Orientational Ordering in Dipolar Particle Systems

The kinetic mechanisms underlying the bottom-up assembly of colloidal particles have been widely investigated in efforts to control crystallization pathways and to direct growth into targeted superstructures for applications, including photonic crystals. Current work builds on recent progress in the development of kinetic theories for crystal growth of bcc crystals in systems with short-range interparticle interactions, accounting for a greater diversity of crystal structures (including fcc and noncubic crystals) and the role of the longer-ranged interactions and orientational degrees of freedom arising in polar systems. We address the importance of orientational ordering processes in influencing crystal growth in such polar systems, thus advancing the theory beyond the treatment of the translational ordering processes considered in previous investigations. The work employs comprehensive molecular dynamics simulations that resolve key crystallization processes and are used in the development of a quantitative theoretical framework based on ideas from time-dependent Ginzburg-Landau theory. The significant effect of orientational ordering (polarization or magnetization) on the crystallization kinetics could be potentially leveraged to achieve solidification kinetics steering through external electric or magnetic fields. Our combined theory/simulation approach provides opportunities for future investigations of more complex crystallization kinetics.