Tuning the membrane rejection behavior by surface wettability engineering for an effective water-in-oil emulsion separation

Abstract

Membrane-based separation is a promising technology to eliminate water impurities from the oil phase. However, it remains a great challenge to separate water from highly emulsified viscous oil owing to the high stability of the water droplets in oil. Herein we report a surface wettability engineering on an alumina ceramic membrane to achieve an efficient separation of a water-in-oil (W/O) emulsion. Silanes with different carbon chain lengths and fluorinated status were introduced to endow the alumina membrane with different surface wettabilities. While all the modified membranes exhibited excellent separation of the W/O without Span 80 (surfactant), the one with amphiphobic wettability and lowest surface energy failed to separate the Span 80 stabilized W/O. The presence of Span 80 reduced the interfacial tension of water droplets, making them easier to deform and penetrate the modified membrane with the lowest surface energy. It reveals that engineering proper surface wettability is the key to separating the oil and water phases. Besides, the modified membranes maintained decent separation performance and stability under long-term run separation of the emulsified W/O.