Abstract
A high-performance photocatalytic ceramic membrane was developed by direct growth of a TiO2 structure on a macroporous alumina support using a hydrothermal method. The morphological nanostructure of TiO2 on the support was successfully controlled via the interaction between the TiO2 precursor and a capping agent, diethylene glycol (DEG). The growth of anatase TiO2 nanorods was observed both on the membrane surface and pore walls. The well-organized nanorods TiO2 reduced the perturbation of the alumina support, thus controlling the hydrolysis rate of the TiO2 precursor and reducing membrane fouling. However, a decrease in the amount of the DEG capping agent significantly reduced membrane permeability, owing to the formation of nonporous clusters of TiO2 on the support. Distribution of the organized TiO2 nanorods on the support was very effective for the improvement of the organic removal efficiency and antifouling under ultraviolet illumination. The TiO2 nanostructure associated with the reactive crystalline phase, rather than the amount of layered TiO2 formed on the support, which was found to be the key to controlling photocatalytic membrane reactivity. These experimental findings would provide a new approach for the development of efficacious photocatalytic membranes with improved performance for wastewater treatment.
Highlights
Membranes are effective tools for the removal of various contaminants from water sources
We described a high-performance photocatalytic membrane based on diethylene glycol (DEG)-assisted TiO2 nanostructure on a porous alumina support for wastewater treatment
To prepare the TiO2 precursor solution, 0.73 g of potassium titanium oxide oxalate dehydrate (PTO) was completely dissolved in deionized water by magnetic stirring, after which DEG was added to the solution dropwise
Summary
Membranes are effective tools for the removal of various contaminants from water sources. As opposed to conventional treatments, membrane processes afford excellent water quality (permeate) and reduce operational costs because of the minimal chemical demands and small footprint [1,2,3,4,5]. Ceramic membranes have many advantages over polymeric membranes, including longer service life, superior thermal and chemical resistance, and better fouling resistance, owing to their hydrophilic surface with a low contact angle [9,10,11,12,13]. Recent advances in membrane fabrication techniques have enabled the development of ceramic membranes with higher reactivities and widespread applications beyond their traditional role as a separation tool.
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