Abstract
Freezing of charged colloids on square or triangular two-dimensional periodic substrates has recently been shown to realize a rich variety of orientational orders. We propose a theoretical framework to analyze the corresponding structures. A fundamental ingredient is that a nonspherical charged object in an electrolyte creates a screened electrostatic potential that is anisotropic at any distance. Our approach is in excellent agreement with the known experimental and numerical results, and explains in simple terms the reentrant orientational melting observed in these so-called colloidal molecular crystals. We also investigate the case of a rectangular periodic substrate and predict an unusual phase transition between orientationally ordered states, as the aspect ratio of the unit cell is changed.
- Received 9 March 2004
DOI:https://doi.org/10.1103/PhysRevLett.93.018304
©2004 American Physical Society