Facile fabrication of durable superhydrophobic and oleophobic surface on cellulose substrate via thiol-ene click modification

“…14 Surface micro-roughness of epicuticular wax is formed with 20-40 μm protruding ganglion. 80 Superhydrophobic surfaces formed with WCAs more than 150°, and at a reduced contact angle hysteresis (CAH <5°). The leaves of lotus plant possess a highly stable superhydrophobic surface compared with many other plants that exhibit WCA of 160˚.…”

“…The hydrophobic surface of lotus leaves (Figure 3 (a-c)) is epicuticular waxy crystalloid, leading to form low surface free energy, micro-/nano-roughness, and superhydrophobicity of surfaces. [80][81][82][83] According to the effectiveness of lotus-simulating micro-/nano-surface roughness, the first artificial superhydrophobic surface was successfully fabricated in 1990s. 20 Several on-surface methodologies such as etching, lithography, biomimetic and stamping were applied to fabricate superhydrophobic, dynamic nanosurface tectonics.…”

“…88 Together, such natural superhydrophobic surfaces incentivize the design of superhydrophobic self-cleaning surfaces and antifouling features, mimicking these natural surfaces. 80,89 Other surfaces like the legs of a water strider possess superhydrophobic surfaces (Figure 3 (h and i)). 90 The leg surface exhibits oriented microsetae that covered with needle morphology and grooved nanostructures.…”

Progress in biomimetic leverages for marine antifouling using nanocomposite coatings

“…14 Surface micro-roughness of epicuticular wax is formed with 20-40 μm protruding ganglion. 80 Superhydrophobic surfaces formed with WCAs more than 150°, and at a reduced contact angle hysteresis (CAH <5°). The leaves of lotus plant possess a highly stable superhydrophobic surface compared with many other plants that exhibit WCA of 160˚.…”

“…The hydrophobic surface of lotus leaves (Figure 3 (a-c)) is epicuticular waxy crystalloid, leading to form low surface free energy, micro-/nano-roughness, and superhydrophobicity of surfaces. [80][81][82][83] According to the effectiveness of lotus-simulating micro-/nano-surface roughness, the first artificial superhydrophobic surface was successfully fabricated in 1990s. 20 Several on-surface methodologies such as etching, lithography, biomimetic and stamping were applied to fabricate superhydrophobic, dynamic nanosurface tectonics.…”

“…88 Together, such natural superhydrophobic surfaces incentivize the design of superhydrophobic self-cleaning surfaces and antifouling features, mimicking these natural surfaces. 80,89 Other surfaces like the legs of a water strider possess superhydrophobic surfaces (Figure 3 (h and i)). 90 The leg surface exhibits oriented microsetae that covered with needle morphology and grooved nanostructures.…”

Progress in biomimetic leverages for marine antifouling using nanocomposite coatings

“…These unique infiltration phenomena have attracted the attention of the scientific community. Numerous studies have focused on this unique surface with a contact angle of >150° and a rolling angle of <10° [ 1 , 2 , 3 , 4 , 5 ]. Various methods for preparing superhydrophobic surfaces have been developed via extensive research, including the sol-gel [ 6 , 7 ], layer-by-layer self-assembly [ 8 , 9 ], and chemical vapor deposition methods [ 10 , 11 ].…”

Preparation of Stable POSS-Based Superhydrophobic Textiles Using Thiol–Ene Click Chemistry

“…[ 10,16 ] Many researchers have focused on developing more efficient methods to prepare amphiphobic and superhydrophobic surfaces with better durability. [ 17–22 ] Recently, Lim et al. developed a superhydrophobic coating with excellent anti‐icing properties on an Al surface using a facile chemical etching and anodization method, followed by surface modification with polydimethylsiloxane (PDMS).…”

A Superhydrophobic and Oleophobic Silicone Sponge with Hierarchical Structures