Figure 1b shows a cross-view SEM image of the template, which is

Figure 1b shows a cross-view SEM image of the template, which is formed by pillars approximately 4 μm long. Figure 1 Scheme and SEM image of the nanostructured Si template. (a) Scheme of the nanostructured Si template (the Si is indicated in blue and Au in orange) and (b) the relative

SEM image in cross-view. The scheme of the nanostructured material after the deposition of the TiO2 layer is shown in Figure 2a in cross view, where the TiO2 is indicated in gray. A cross-view TEM image of the structure is shown in Figure 2b. The micrograph exhibits the Si substrate at the bottom of the structure; the Au nanoparticles involved in the wet etching process are visible in dark contrast; the top of the Au nanoparticles and the Si structures resulted to be uniformly covered by the TiO2 layer (10 nm thick). The analyses confirmed the excellent conformality of the deposition, I-BET151 chemical structure thanks to the good diffusion Selleck FHPI of the precursors inside the nanostructured template, so the TiO2 coverage came up to the bottom of the Si template, despite the high aspect ratio of the nanostructures (approximately 100).

Figure 2c shows a schematic plan-view of the sample in order to give a visual idea of the template structure with nanocavities, while Figure 2d reports the relative TEM image. Here, the light area indicates the nanocavities of the porous structure, Abiraterone price while the dark gray area indicates the Si covered by the titania layer. A 100% enhancement of the TiO2 exposed surface area with respect to the flat film has been calculated by using the TEM data from several images similar to Figure 2d, thanks to the Gatan Digital Micrograph program. The diffraction pattern reported in Figure 2e unequivocally showed a polycrystalline

anatase phase of the TiO2, in good agreement with the literature [21]. X-ray diffraction analyses indicated an average grain size of approximately 15 nm. The polycrystalline structure of the titania films resulted to be the same for both the TiO2/Si-template and the TiO2 flat sample. Figure 2 Schemes and TEM images of the nanostructured Si template covered by the TiO 2 and its diffraction pattern. (a) Scheme of the nanostructured Si template after the TiO2 deposition and (b) the relative TEM image in cross-view. (c) Scheme of the sample after the TiO2 deposition and (d) the relative TEM image in plan-view. (e) Diffraction pattern showing silicon and polycrystalline TiO2. The PLX-4720 chemical structure photocatalytic activity of the synthesized materials was tested by the degradation of two dyes: MB, which is a dye of the thiazine family, and MO, which is a dye of the azo family (about the toxicity effects of these two dye families, the reader can refer to the ‘Background’ section). Figure 3 illustrates the discoloration measurements.

Comments are closed.