2020
DOI: 10.1002/adfm.201910665
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Microskeleton‐Nanofiller Composite with Mechanical Super‐Robust Superhydrophobicity against Abrasion and Impact

Abstract: Superhydrophobic surfaces have promised tremendous applications in living and industrial areas for the past two decades. Real applications, however, meet challenges, with the central concern being the robustness to resist mechanical abrasions and impacts. Here, a revolutionary strategy is proposed to create a microskeleton-nanofiller (MSNF) film with exceptionally mechanical superstable superhydrophobicity. The strategy is conceptually different from the traditional superhydrophobic 3D microskeleton, because a… Show more

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Cited by 83 publications
(51 citation statements)
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“…19). Even after 3,000 cycles under a 250 g load, the θ C is larger than ~150° and θ R is less than 10°, a performance at least 10 times higher than our previous work 30 and other existing studies [31][32][33][34] (Fig. 3a-c, Supplementary Movie 4).…”
contrasting
confidence: 57%
“…19). Even after 3,000 cycles under a 250 g load, the θ C is larger than ~150° and θ R is less than 10°, a performance at least 10 times higher than our previous work 30 and other existing studies [31][32][33][34] (Fig. 3a-c, Supplementary Movie 4).…”
contrasting
confidence: 57%
“…The C 1s peak is composed of CF 3 (293.8 eV), CF 2 (292.4 eV), C-O/C-OH (286.5 eV), and C-C/C-H/C-Si (284.8 eV) peaks ( Figure 1 I). The Si 2p peak is composed of Si-C (102.0 eV), Si-O (103.3 eV) and Si- O -Si (103.9 eV) peaks ( Figure S4 ) ( Chen et al., 2020 ; Qing et al., 2020 ). The F content reaches 37.84 at%, indicating presence of abundant perfluorodecyl groups on the surface of the fabric ( Li et al., 2019a ).…”
Section: Resultsmentioning
confidence: 99%
“…[ 1–13 ] Many published works are devoted to improving the mechanical robustness of superhydrophobic coatings by optimizing coating design or synthesizing new matrix polymer. [ 14–24 ] However, specialized design for the chemical resistance of coatings, especially for acid and alkali resistance, is usually neglected, limiting their durability. Alkali‐susceptible inorganic particles like slica, zinc oxide, and titanium dioxide are widely used to offer micro‐nano roughness in superhydrophobic coatings, significantly reducing their chemical resistance.…”
Section: Introductionmentioning
confidence: 99%