Development in modeling submicron particle formation in two phases flow of solvent-supercritical antisolvent emulsion

The use of a supercritical Solvent (S)–Antisolvent (AS) process (SAS) for fine particle production is finding widespread industrial applications. The perfection of this technology requires insight into many basic laws of interface and colloid science. In SAS the solute is dissolved in an organic solvent and the solution is sprayed into a near critical AS stream. SAS is a complex process involving the interaction of jet hydrodynamics, droplet formation, mass transfer, phase equilibrium, intra-droplet nucleation, and microcrystal growth. A complete description would have to take into account all of these processes; however, such a model is not currently available. In the two-phase flow of an S/AS emulsion, S diffuses from droplets into AS, while AS dissolves inside the S droplets. S replacement by AS (Supercritical CO 2) causes solute supersaturation in the droplets. When it occurs near the critical point of the S/AS emulsion (80 bar, 32 °C), intra-droplet nucleation and precipitation of the solute occurs. The possibility of solute particle production and the particle size is controlled by the droplet size and by the interrelationship between three time scales. These are the droplet mass transfer time τ N , the nucleation time τ N , i.e., the time necessary for one particle nucleus to form in one droplet, and the droplet residence in the supersaturated stream τ res. An approximate analytical theory for intra-droplet nucleation is developed and the conditions necessary for nanoparticle production are established. The smaller the droplet dimension and the lower the solute concentration, the smaller the particle dimension that is obtained. The recent success in membrane emulsifying may be used for the production of micron-sized droplets. After the AS stream is saturated with S due to partial dissolution of the droplets, a quasi-equilibrium between the droplets and AS stream occurs and a steady and uniform zone with intra-droplet supersaturation is formed downstream. But τ res > τ N is necessary for one nucleus formation per droplet, i.e., τ res has to be much longer than that reported in the literature (10 − 3 s), because τ N increases with decreasing droplet dimension. Accordingly, a long residence time version of the SAS process ( τ res ∼ 1 s) is necessary. However, a long τ res is problematic because of micro-droplet turbulent coagulation. Since an increase in τ res is difficult, a decrease in τ N by means of an increase in S becomes significant. This is ac