(362g) Understanding the Mechanisms of Crystallization and Reconfiguration of Anisotropic Nanoparticle Superlattices

In this work, we elucidate the complex phase behavior and corresponding crystallization pathways of polymer-grafted gold nanocubes into highly ordered superlattices using experimental, computational, and theoretical techniques. LCTEM experiments reveal a solvent-dependent self-assembly phase behavior, where a series of hexagonal rotator, rhombic, and square-like phases are observed with increasing solvent polarity. To explain these observations, we develop a computational model that reproduces the experimental phase behavior and show that the variable charge screening by the solvent drives the assembly of the nanocubes into different phases. Interestingly, the self-assembly of the different phases follow distinct kinetic pathways; in particular, the assembly of the rhombic phase proceeds via a decoupling of translational and orientational order. Moreover, we demonstrate a reversible transition between the square-like and rhombic phases, and find a hexagonal rotator-like intermediate phase along the transition pathway. These findings open the door for understanding—and hence manipulating—complex microscopic crystallization pathways and phase transition kinetics of anisotropic nanoparticles.