Milosevic, I.Rtimi, S.Jayaprakash, A.van Driel, B.Greenwood, B.Aimable, A.Senna, M.Bowen, P.2018-12-132018-12-132018-12-132018-11-0110.1016/j.colsurfb.2018.07.035https://infoscience.epfl.ch/handle/20.500.14299/152162WOS:000447575400054Fluorinated-titanium dioxide (TiO2-F) nanoparticles in a pure anatase polymorph was precipitated from solution by hydrolysis of titanium oxychloride, using urea and ammonia as precipitation agents and potassium fluoride as a source of fluorine anion. A further wet attrition milling in presence of glycine completed by a heat treatment allowed an additional nitrogen doping of TiO2 (TiO2-F&N-HT). The morphology and crystalline structure of the as-synthesized powder was determined by transmission electron microscopy (TEM) and X-ray diffraction (XRD) and showed that TiO2 powder was composed of nanoparticles with narrow size distribution which crystallized in the anatase phase. X-ray photoelectron spectroscopy (XPS) revealed that fluorine and nitrogen are present in TiO2 as surface fluorination and interstitial doping, respectively. UV-vis diffuse reflectance spectroscopy (DRS) showed an increased optical absorption in the visible for TiO2-F&N-HT sample. Under visible light irradiation, TiO2-F nanoparticles showed a high photocatalytic performance, showing the high potential of an improved surface fluorination for Escherichia coli (E, coli) disinfection in suspension. These results show the importance of anatase-TiO2 nanoparticles synthesis and modification by using a wet chemical approach leading to low aggregation and high specific surface area for effective bacterial inactivation. The co-doped TiO2-F&N-HT powder showed slightly improved performance compared to the fluorinated sample. The significant degree of aggregation after the heat treatment is postulated as being a limiting factor in its photocatalytic activity.BiophysicsChemistry, PhysicalMaterials Science, BiomaterialsChemistryMaterials Sciencetio2anatasefluorinationn-dopedinterstitialaggregationantibacterialphotocatalyticdoped tio2 nanoparticlesantibacterial activityescherichia-coliparticle-sizenitrogenoxidationmechanismfacetsdegradationstabilitytext::journal::journal article::research article