Exploring the potential of photocatalytic dual layered hollow fiber membranes incorporated with hybrid titania nanotube-boron for agricultural wastewater reclamation

• Published in: Separation and purification technology Vol. 275; p. 119136
• Main Authors: Subramaniam, M.N., Goh, P.S., Lau, W.J., Ismail, A.F.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.11.2021
• Subjects: AT-POME; Colour removal; Filtration; Photocatalysis; SMPR; Colour removal; SMPR; AT-POME; Filtration; Photocatalysis
• ISSN: 1383-5866; 1873-3794
• DOI: 10.1016/j.seppur.2021.119136

[Display omitted] •Boron doped TNT immobilized on the outer layer of a dual layered PVDF hollow fiber membrane.•A finger-like structure on both outer and inner layer, sandwiching a dense interlayer.•PVDF-L2% exhibited a maximum flux of 39.62L/m2h and colour removal of 79.42%.•Membrane recovered more than 95% of performance after 4 filtration cycles, exhibiting antifouling propensity.•Long term study confirms membrane usability over 20 days. The emergence of hybrid photocatalytic membranes has provided a new direction in search of efficient technologies to separate and degrade pollutants present in wastewaters. Colour pigments originated from different sources including agricultural waste pose serious threats towards water bodies as their presence will lead to multiple environmental problems. This study investigated the potential of a photocatalytic dual layered hollow fiber membrane (DLHFM) incorporated with boron doped titania nanotubes (TNT-B) photocatalyst for the photodegradation and removal of colour pigment molecules present in aerobically treated palm oil mill effluent (AT-POME). The colour removal efficiencies and separation performance of the DLHFM were evaluated through a submerged membrane photo reactor (SMPR) system driven by visible light. Polyvinylidene fluoride-based DLHFM loaded with 2% of photocatalyst (PVDF-L2%) exhibited the best membrane performance with a flux of 39.62 L/m2h and colour removal efficiency of 79.42%. The controlled distribution of photocatalysts as well as the synergistic combination of membrane filtration and photodegradation concertedly contributed to the improvement in membrane’s performance. 95% of flux and colour removal efficiency were sustained after four filtration cycles. The membrane exhibited efficient performance in terms of consistent flux and colour removal efficiency after 20 days of continuous photocatalytic filtration, implying their high long-term stability. This study highlights the efficiency and potential of visible light photocatalytic membranes in treating colour laden wastewaters.