Electrospun Bi3+/TiO2 nanofibers for concurrent photocatalytic H2 and clean water production from glycerol under solar irradiation: A systematic study.

In this study, bismuth/titanium oxide (Bi3+/TiO 2) composite nanofibers (herein after referred to as Bi/TiO 2) with enhanced physicochemical properties thus photocatalytic efficiency are successfully synthesized via electrospinning which maximizes the uniformity of Bi and Ti at molecular level. Bi/TiO 2 shows positive characterization through anatase crystallinity, large light utilization rate, high specific surface area and low electron holes pair recombination rate as a result of the novel materials synthesis approach. Glycerol as a typical pollutant of industrial wastewater, is used here to demonstrate the concurrent production of chean water and H 2 over the well synthesized Bi/TiO 2. Bi is incorporated to extend the light absorbance capability of TiO 2 to visible light region. Experimental data shows that 3% Bi/TiO 2 exhibits the highest H 2 generation and Total Organic Carbon (TOC) removal. The reduction of TOC of 8% means the conversion of glycerol into H 2 has been achieved, which is in favor of the production of clean water from highly polluted glycerol wastewater. An optimization study is undertaken by varying the calcination temperature to investigate properties-activity relationship of the new photocatalyst, which exhibited higher photocatlytic efficiency under both UV–visible and visible light compared with that of bare TiO 2. The mechanism illustration is derived from the novel materials synthesis and property optimization to explain the rationale behind this interesting phenomenon. It is worth to note that Bi/TiO 2 nanofibers represent a promising photocatalyst for environmental remediation and sustainability where it can be potentially used in glycerol by-product or waste from the industry under the renewable solar irradiation to generate H 2 and clean water simultaneously. [Display omitted] • Bi-incorporated TiO 2 nanofibers exhibited to be able to concurrently generate H 2 and clean water under solar irradiation. • Enhanced physico-chemical properties of Bi/TiO 2 nanofibers. • Enlarged specific surface area & unique mesoporosity. • Enhanced light absorption capability for better photocatalytic reaction, and. • Well-dispersed heterojunctions for an efficient electrons-holes separation. [ABSTRACT FROM AUTHOR]