Morphological control of CaCO3 films with large area: effect of additives and self-organization under atmospheric conditions.

Hierarchically structured CaCO(3) films were synthesized at atmospheric conditions (room temperature and 1 atm) without the use of templates or amphiphilic molecules in this process. The resulting CaCO(3) film was formed by self-organization between Ca(OH)(2) and aqueous CO(2). The building blocks of the CaCO(3) film were thought to be CaCO(3) primary nanoparticles that aligned to build higher level structures with greater size, called mesocrystals, depending on the additives.

A new approach to the synthesis of functional thin films: hierarchical synthesis of CaCO3 thin films and their transformation into patterned metal thin films.

A patterned metal thin film was synthesized based on a new approach that allows the formation of thin films with complex shape, hierarchical organization, and controlled size under ambient conditions in an aqueous environment. By using a general coating system, a CaCO(3) thin film was transformed into a patterned metal thin film with functional properties, such as adhesion and hydrophobicity. Atomic force microscopy (AFM) and surface-profiling experiments were carried out to measure the adhesion between the probe tip and the substrate and to determine the film thickness.

New approach for fabrication of folded-structure SiO2 using oyster shell.

Inspired by the phenomenological differences of layers in oyster shell and the morphological mimicry of SiO(2) thin film, a folded-structure SiO(2) was created by simple spray deposition system. The folded-structure SiO(2) was analyzed by scanning electron microscopy, energy dispersive spectrometer and microindentation. At the molecular level, the chalky and the folia were assembled and determined through biomineralization based on the differences of soluble protein in layers.