Theories of nanoparticle and nanostructure formation in liquid phase
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Abstract
Nanoparticles (NPs) and nanostructured materials exhibit shape- and size-dependent properties that are desired for a wide variety of applications, such as catalysis, sensing, drug delivery, energy production, and storage. In view of this, it is essential to produce well-defined NPs and nanostructures with desired characteristics, to understand their formation and growth mechanisms, and to define the critical size below which they act differently from bulk materials in order to develop synthetic strategies. For example, quantum dots (below 20nm) are mainly single nanocrystals characterized by a single-domain crystalline lattice without grain boundaries. These tiny individual crystals differ drastically from bulk polycrystalline materials. In fact, existing investigations indicated that ordered polycrystalline particles are preferably formed at high supersaturations, where rapid nucleation generates many NPs, which subsequently tend to aggregate randomly at high NP concentrations. Single crystals, such as quantum dots, form at low supersaturations. The reduction of the supersaturation to a level at which primary NPs are still formed in solution yields mesocrystals. This chapter discusses the advanced nucleation and growth theories that are used to explain the growth of the obtained nanoparticles and nanostructures to the desired structures.