Having a ball: Crystallization in a sphere

A research group at Institute of Industrial Science, The University of Tokyo and Fudan University led by Hajime Tanaka and Peng Tan used a droplet of a colloid -- a dispersion of liquid particles in another liquid, like milk -- as a model for single atoms or molecules in a sphere. Unlike single atoms or molecules, which are too small to easily observe, the colloid particles were large enough to visualize using a microscope. This allowed the researchers to track the ordering of single particles in real time during crystallization.

"We visualized the organization process of colloid particles in numerous droplets under different conditions to provide a picture of the crystallization process in a sphere," says Tan.

Based on their observations, the team proposed that the crystallization process involved three stages: initial ordering on the surface "skin" of the droplet, nucleation and growth in the core of the droplet, and then slow ripening of the whole structure. First, a skin consisting of a single layer of ordered colloid particles rapidly formed on the droplet surface. Next, crystallization occurred in the core of the droplet, far from the crystallized skin. The competition between crystallization in these two regions controlled the structure of the final crystal.

The researchers found that the "soft" (long-range) interactions between the negatively charged colloid particles affected their organization and the resulting crystal structure. These soft interactions are dominated by kinetics, that is, the interactions that form the fastest, rather than those that use the least energy to give the thermodynamically stable structure, illustrating that kinetics plays an important role in crystallization in a confined space. It was already known that thermodynamics contributes strongly to the final structure of crystals. The team's findings confirmed that kinetics are also integral, furthering our knowledge of crystallization in confined spaces.

"This research deepens our understanding of the crystallization process in geometrically constrained systems, leading researchers one step closer to achieving controlled growth of crystals at a very small scale," explains Tanaka.

Detailed knowledge of the crystal formation process in confined systems may enable crystals with designed structures, such as nanoparticles for specific electronics applications, to be obtained, giving researchers greater ability to control the structure and thus the properties of valuable materials.