We report microwave-assisted heating as an effective and versatile method for the formulation of particle-stabilized water-in-oil emulsions. This approach offers distinct advantages in terms of rapid processing compared with conventional mixing and thermal techniques. Upon microwave irradiation, water in the binary oil/water system undergoes selective heating, leading to localized vaporization. The vapor subsequently condenses in the overlaid particle-laden oil phase, generating droplets that are stabilized by colloidal particles. This process enables the production of emulsions with tunable droplet sizes controlled by the microwave exposure time and heating temperature, holding time at the target temperature, and oil-to-water ratio. The versatility of the methodology is further investigated by considering different types of stabilizers, including solid particles (hydrophobic fumed silica, hematite, magnetite, alumina) and surfactant (Span 80), and by considering different types of oils (n-decane, liquid paraffin, and sunflower oil). The resulting emulsions are characterized by a pronounced degree of polydispersity, with droplet diameters ranging from 3 to 115 μm depending on heating temperature and exposure time. Emulsion morphology and type are systematically investigated by using both optical and confocal microscopy, providing insight into droplet size distribution and stabilization mechanisms. Furthermore, we compare this methodology with a laboratory-scale homogenization process. Microwave-assisted Pickering emulsification requires 4 × 104 J of energy, whereas the homogenization process consumes 2 × 106 J to produce Pickering emulsion droplets of comparable size. These results highlight the versatility of microwave-assisted emulsification and emphasize its potential as a broadly applicable strategy for producing particle-stabilized emulsions across a wide range of systems.
Murmu et al. (Sun,) studied this question.