| Literature DB >> 33799849 |
Clayton Farrugia1, Alessandro Di Mauro2, Frederick Lia3, Edwin Zammit3, Alex Rizzo3, Vittorio Privitera2, Giuliana Impellizzeri2, Maria Antonietta Buccheri4, Giancarlo Rappazzo4, Maurice Grech1, Paul Refalo5, Stephen Abela1.
Abstract
Photocatalysis has long been touted as one of the most promising technologies for environmental remediation. The ability of photocatalysts to degrade a host of different pollutants, especially recalcitrant molecules, is certainly appealing. Titanium dioxide (TiO2) has been used extensively for this purpose. Anodic oxidation allows for the synthesis of a highly ordered nanotubular structure with a high degree of tunability. In this study, a series of TiO2 arrays were synthesised using different electrolytes and different potentials. Mixed anatase-rutile photocatalysts with excellent wettability were achieved with all the experimental iterations. Under UVA light, all the materials showed significant photoactivity towards different organic pollutants. The nanotubes synthesised in the ethylene glycol-based electrolyte exhibited the best performance, with near complete degradation of all the pollutants. The antibacterial activity of this same material was similarly high, with extremely low bacterial survival rates. Increasing the voltage resulted in wider and longer nanotubes, characteristics which increase the level of photocatalytic activity. The ease of synthesis coupled with the excellent activity makes this a viable material that can be used in flat-plate reactors and that is suitable for photocatalytic water treatment.Entities:
Keywords: anodic oxidation; morphology; nanotubes; photocatalysis; titanium dioxide; water treatment
Year: 2021 PMID: 33799849 PMCID: PMC7998466 DOI: 10.3390/nano11030708
Source DB: PubMed Journal: Nanomaterials (Basel) ISSN: 2079-4991 Impact factor: 5.076