| Literature DB >> 34205225 |
Xuan Wang1, Weihua Ao1, Sijia Sun1, Han Zhang1, Run Zhou1, Yangzi Li1, Jie Wang1, Hao Ding1.
Abstract
Superhydrophobic coatings with intelligent properEntities:
Keywords: PDMS; TiO2; photocatalytic activity; superhydrophobicity; tunable adhesion
Year: 2021 PMID: 34205225 PMCID: PMC8229519 DOI: 10.3390/nano11061486
Source DB: PubMed Journal: Nanomaterials (Basel) ISSN: 2079-4991 Impact factor: 5.076
Figure 1Preparation flowchart of superhydrophobic A-SiO2/N-TiO2@PDMS coating.
Figure 2(a) The changes in the coating’s wettability and adhesion to water droplets before and after UV irradiation and calcination. (b) The adhesion force of the coating to a water droplet before and after UV irradiation. (c) The changes in WCAs of the coating after alternate UV irradiation and calcination.
Figure 3Schematic diagram of the self-cleaning process.
Figure 4(a) Photodegradation of methyl orange by A-SiO2/N-TiO2@PDMS and other samples; (b) simulation experiment of the “lotus effect”.
Figure 5Wettability of the surfaces of (a) a glass slide, (b) the A-SiO2/N-TiO2@PDMS coating after UV irradiation, and (c) the mechanically damaged A-SiO2/N-TiO2@PDMS coating after UV irradiation to water, HCl, NaOH, and methyl orange solution droplets, respectively; wettability of the surfaces of (d) wood, (e) foam, (f) concrete, and (g) brick before (left) and after (right) being sprayed with A-SiO2/N-TiO2@PDMS and UV irradiation to water, HCl, NaOH, and methyl orange solution, respectively.
Figure 6The changes in (a) WCAs and (b) photocatalytic degradation effects of the A-SiO2/N-TiO2@PDMS coating after being placed outdoors for 3 months.
Figure 7SEM images and EDS element mapping data of A-SiO2, N-TiO2, and A-SiO2/N-TiO2. (a) SEM image of A-SiO2; (b) SEM image of N-TiO2; (c) SEM image of A-SiO2/N-TiO2; (d) SEM image of the A-SiO2/N-TiO2@PDMS coating surface; (e) EDS element mapping images of O, Si, and Ti of A-SiO2/N-TiO2; (f) TEM of A-SiO2/N-TiO2; (g) HRTEM image of A-SiO2/N-TiO2; (h) FFT analysis of a selected area of A-SiO2/N-TiO2.
Figure 8XRD patterns of A-SiO2, N-TiO2, A-SiO2/N-TiO2, and A-SiO2/N-TiO2@PDMS.
Figure 9FT-IR spectra of A-SiO2/N-TiO2, PDMS, A-SiO2/N-TiO2@PDMS, and A-SiO2/N-TiO2@PDMS after UV irradiation; A-SiO2/N-TiO2@PDMS after calcination at 400 °C; and A-SiO2/N-TiO2@PDMS after 3 cycles of calcination and UV irradiation.
Figure 10(a) Full-scan XPS spectra of A-SiO2/N-TiO2, A-SiO2/N-TiO2@PDMS, A-SiO2/N-TiO2@PDMS after UV irradiation; A-SiO2/N-TiO2@PDMS after calcination at 400 °C; and A-SiO2/N-TiO2@PDMS after three cycles of UV irradiation and calcination. (b–f) Narrow-scan spectra of O 1s in the above spectra.
Figure 11Wetting state and surface microstructure of the A-SiO2/N-TiO2@PDMS coating under different conditions.