Abstract
A systematic investigation of the photocatalytic activity (PCA) of nanostructured ZnO films showed how this is directly affected by the films' morphology at different scales, from the macroscale morphology of films (e.g. thickness and surface area), to the microscale feature arrangement (e.g. aligned vs. randomly oriented structures or interpenetrated ones), to the nanoscale structure (e.g. crystal size and orientation). The interest in immobilizing photocatalysts in water treatment stems from concerns about the potential toxicity of their slurry form, which requires expensive downstream removal. Immobilisation, though, leads to a reduction in PCA, generally attributed to a lower surface area. By reducing the films' feature size to the nanoscale, an immobilized photocatalyst with high surface area can be achieved. At this scale, however, feature structuring and morphology become important as they determine the interaction between light and the photocatalytic material. In this work, nanostructured ZnO films with different morphology, arrangement and structure were produced by electrochemical anodization of zinc and were tested using the degradation of phenol in a batch reactor as a model system. Results show that the PCA for immobilized catalysts can be optimised by controlling microscale arrangement (light absorbance capacity) and nanoscale structure (crystal size and orientation) rather than macroscale morphology (surface area). These results provide a clear direction to maximising the photocatalytic activity of immobilised photocatalysts for the removal of organic pollutants from water.
Highlights
A systematic investigation of the photocatalytic activity (PCA) of nanostructured ZnO films showed how this is directly affected by the films’ morphology at different scales, from the macroscale morphology of films, to the microscale feature arrangement, to the nanoscale structure
It emerges that a major challenge in designing immobilised photocatalysts is how to separate the effect of macroscale morphology from that microscale feature arrangement and nanoscale structuring
By studying the degradation of phenol in a batch reactor, a systematic analysis of the effect of structuring and morphology of immobilised photocatalysts on PCA was conducted in this work
Summary
The ones with a higher surface area (e.g. rodlike morphology).[13]. A review on ZnO suspensions for photocatalytic applications highlighted the importance of morphology in optimizing the degradation of these materials, focusing primarily on the effect of surface area, crystallinity and shape of the nanostructures.[14]. Nanostructured ZnO films (ZnO-NFs) were manufactured via the electrochemical anodization of zinc metal foils as it enables the production of ZnO nanostructures with a variety of morphologies and structures, and controlled crystallinity, crystal size and dimensions.[16] The analysis includes the effect of morphology on the adsorption process (measured through adsorption–desorption experiments, surface area and crystallinity) and the interaction between light and the photocatalytic material (measured by light absorbance analysis). Kinetic constants were calculated as a straight fit on the linear portion of a log plot of concentration vs. time
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
