Phytic acid metal complex as precursor for fabrication of superhydrophilic membrane with photo-Fenton self-cleaning property for microalgae dewatering and oil/water emulsion separation

Abstract

Membrane technology is regarded as one of the most effective approaches for microalgae dewatering in the biofuel production industrial and oil/water emulsion separation. However, it inherently suffers from the issue of membrane fouling, particularly irreversible membrane fouling, which is hard to remove by physical methods. Herein, a robust superhydrophilic membrane combined with photo-Fenton self-cleaning property was developed for microalgae dewatering and oil/water emulsion separation. Phytic acid (PA) and FeIII formed a hydrophilic PA-FeIII complex on the polyethersulfone (PES) membrane as the precursor for the in situ growth of β-FeOOH nanorods. When used for microalgae filtration, the irreversible fouling that blocked membrane pores could be degraded by the photo-Fenton reaction. Hence, the obtained PES/PA@β-FeOOH membrane possessed a flux recovery rate (FRR) of 90.2 % (within 30 min), which was significantly higher than that of the PES membrane (32.9 %). The proteins and polysaccharides (extracellular organic matter) attached on the PES/PA@β-FeOOH membrane with photo-Fenton cleaning were 11.2 and 9.1 mg/m2, which was considerably lower than that of PES after hydraulic cleaning (184.1 and 334.9 mg/m2). Moreover, due to the superhydrophilic, the prepared PES/PA@β-FeOOH membrane also exhibited excellent oil/water emulsion separation ability. This work presents a facile and mild strategy to design an anti-fouling coating with superhydrophilic and photo-Fenton activity, which can be used in membrane technology for microorganism filtration and wastewater treatment.