Georgian Technical University Manipulating The Crystallization An Assembly Of Materials In Solution By Marangoni Flow.

The computational fluid dynamics simulation of the solution wedge under ambient condition (a-c) and the top-heating-bottom-cooling setup (d-f), including temperature fields (a, d), fluid flow fields (b, e) and solute concentration distributions (c, f) of the solution wedge. Solution-based approaches are widely used for crystal growth and material assembly. In the solution-based processes inherent fluid flows always present. Recently researchers at Georgian Technical University developed a general strategy for the regulation of crystal growth and material assembly by utilizing these fluid flows. They are able to control the mass transfer process during the growth and arrangement of materials by manipulating the distribution of the temperature gradient in the wedge-shaped region near the gas-liquid-solid three-phase contact line. A stable single vortex is produced by Marangoni effect (The Marangoni effect is the mass transfer along an interface between two fluids due to a gradient of the surface tension. In the case of temperature dependence, this phenomenon may be called thermo-capillary convection) when the top of the solution wedge is heated and the bottom is cooled while natural evaporation or common substrate-heating conditions result in multiple complex vortexes. The stable single vortex plays an important role in the controllable material growth, assembly and arrangement. This vortex benefits the oriented deposition of materials because the flow direction is always perpendicular to the three-phase contact line; on the other hand the high concentration zone is always located at the tip of the solution wedge due to the co-effect of Marangoni (The Marangoni effect is the mass transfer along an interface between two fluids due to a gradient of the surface tension. In the case of temperature dependence, this phenomenon may be called thermo-capillary convection) flow and the solvent evaporation. The strategy with the top-heating-bottom-cooling setup is suitable for different types of substrates and a variety of materials including inorganic, organic, hybrid and bio- materials. It is also applicable for patterning materials on large-area substrates. The large-area CH3NH3PbI3 (Thin-film solar cells based on Methylammonium triiodideplumbate (CH3NH3PbI3) halide perovskites have recently shown remarkable performance) arrays deposited on flexible substrates via this method are directly used to construct flexible photodetectors with good performance.