Abstract
Wastewaters from precious metal industries contain high amounts of noble metals, but their efficient recycling is hindered by the wastewater complex composition. Here, we propose an innovative approach for the efficient recovery of noble metals contained in these metal-enriched wastewaters as precursors for the synthesis of noble metal nanoparticles (NPs) and supported metal catalysts. Silver NPs were synthesized from Ag-enriched wastewater and then deposited on TiO2 to prepare photocatalysts. Then, further promotion of the photocatalytic activity of Ag-modified TiO2 was achieved by the addition of as little as 0.5 wt.% of Au. STEM-EDS analyses proved that Au NPs were located on Ag or AgOx nanoparticles. The contact between the two metal-containing NPs results in charge transfer effects, appreciable both in terms of oxidation states determined by XPS and of optical properties. In particular, the plasmon band of Au NPs shows photochromic effects: under UV light irradiation, bimetallic samples exhibit a blue-shift of the plasmon band, which is reversible under dark storage. The activity of the materials was tested towards ethanol photodegradation under UV light. Adding 0.5 wt.% Au NPs resulted in a promoted activity compared to Ag-TiO2, thus showing synergistic effects between Au and Ag. Ethanol was completely converted already after 1 h of UV irradiation, acetaldehyde was formed as the main oxidation product and fully degraded in less than 180 min. Notably, bimetallic samples showed ethylene formation by a parallel dehydration mechanism.
Highlights
Noble metal nanoparticles (NPs) absorb light because of the localized surface plasmon resonance (LSPR) phenomenon [1]
We tested the samples in the photocatalytic oxidation of ethanol as a model compound, considering that it is estimated to be the most important volatile organic compounds (VOCs) emitted by mass
Silver nanoparticles can be electrochemically synthesized from wastewaters enriched in silver ions and can be used to decorate the surface of a pigmentary TiO2 in order to obtain an active metal-modified photocatalyst
Summary
Noble metal nanoparticles (NPs) absorb light because of the localized surface plasmon resonance (LSPR) phenomenon [1]. Silver NPs coupled with large band gap semiconductors, such as TiO2 show many advantages with respect to the unpromoted oxide semiconductor regarding materials energy and sustainability, such as plasmon-enhanced photocatalytic activity [2,3], improved antibacterial properties [4], extended visible light absorption for solar energy conversion and promoted H2 production [5]. Ag2 O can be coupled with TiO2 , which has been reported to result in a large improvement of photocatalytic activity under UV/vis irradiation as well as high antimicrobial properties [6]. The use of noble metals is still limited by their high cost [7], search for alternatives is one of the greatest interest topics of nowadays. An innovative approach to recover them could be using these metal-enriched wastewaters as a precursor for the synthesis of noble metal nanoparticles, which can be in turn utilized to synthesize supported metal catalysts
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