Biomimetic super durable and stable surfaces with superhydrophobicity

• Published in: Journal of materials chemistry. A, Materials for energy and sustainability Vol. 6; no. 35; pp. 16731 - 16768
• Main Authors: Jing, Xueshan, Guo, Zhiguang
• Format: Journal Article
• Language: English
• Published: Cambridge Royal Society of Chemistry 2018
• Subjects: Biomimetics; Chemical damage; Coatings; Durability; energy; High temperature; Hydrophobic surfaces; Hydrophobicity; Irradiation; manufacturing; mechanical damage; Organic chemistry; Restoration; Saline solutions; Self healing materials; Service life; Structural damage; Surface energy; Surface properties; temperature; topography; Ultraviolet radiation
• ISSN: 2050-7488; 2050-7496; 2050-7496
• DOI: 10.1039/c8ta04994g

Owing to their specialized functions and various potential applications, bioinspired superwettable surfaces have captured much attention. Nevertheless, superhydrophobic surfaces are vulnerable to destruction under various harsh conditions when applied in industry and life science, limiting larger-scale applications. Herein, the subject of prolonging lifetime is comprehensively discussed by means of analyzing the breakdown mechanism, which is influenced by the parameters of surface structures. First of all, the mechanical durability of surfaces can be highly enhanced to endure mechanical damage, through introducing elastic materials and exceptionally stable rough structure. Secondly, chemically stable superhydrophobic coatings are introduced to resist UV ultraviolet irradiation, acid/base/salt solutions and high temperatures. Thirdly, a certain number of vital advances are summarized regarding surface self-healing properties, which can greatly prolong the service life of surfaces through releasing low surface energy agents and regenerating topographic structures. Last but not least, the easy repairability of superhydrophobic coatings is beneficial for chemical damage resistance on account of the fast restoration of original characteristics. Conclusions and outlooks concerning constructing super stable and durable bioinspired superwettable surfaces are revealed and discussed in this review, aimed at extending the application of these surfaces to our daily life and industrial manufacture. A detailed introduction to superhydrophobic surfaces with superior durability characteristics and comprehensive discussion about fabrication approaches to prolong surface lifetimes are presented in this review, which is expected to inspire a number of scholars to fabricate more durable superhydrophobic materials.