Figure - available from: Journal of Materials Science
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Picture a and SEM b images of the lotus leaf. SEM images of the SSM c, d. SEM images and EDS spectra of the surface e–h and cross-section of the PVDF@SiO2-coated SSM i–l
Source publication
Superhydrophobic surfaces have attracted extensive attentions due to their promising potential for broad applications. However, the complex preparation process and expensive low-surface-energy modifier significantly constrain its large-scale practical applications. Thus, construction of robust liquid-repellent surfaces via a facile and versatile ap...
Citations
Long‐lasting hydrogen evolution and efficient dew harvest is realized via electrospinning a polyvinylidene fluoride (PVDF) membrane on hybrid hydrogels embedded with photocatalytic g‐C 3 N 4 /Pt nanosheets. Due to the hindrance of water evaporation by the hydrophobic PVDF membrane, the drying process of the hybrid hydrogels significantly slows down. Hence, the g‐C 3 N 4 /Pt nanosheets can continue working on photocatalytic splitting of the water molecules in the hydrogels. When the thickness of the PVDF membrane is 48 μm, the hydrogen evolution rate can reach 2,543 μmol h ⁻¹ g ⁻¹ , which is 38% more than that of the hybrid hydrogel without covering. Therefore, the hybrid hydrogels covered with PVDF membrane are able to work with high efficiency for 12 h, sufficient for hydrogen evolution during the daytime. In addition, the hydrophobic PVDF membrane and hydrophilic hydrogels construct a Janus structure and induce a fast transport of water molecules from the hydrophobic to hydrophilic side. It is beneficial for the rapid collection of dew in the morning. Based on the long‐lasting hydrogen evolution and efficient dew harvest, the present hybrid hydrogels covered with PVDF membrane are very suitable for the environment rich in solar resource and lack of water supply, such as desert or prairie.
