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All-perfluoropolymer, nonlinear stability-assisted monolithic surface combines topology-specific superwettability with ultradurability

Wanbo Li, Chiu-Wing Chan, Zeyu Li, Sin-Yung Siu, Siyu Chen, Han Sun, Zeyu Liu, Yisu Wang, Chong Hu, Nicola M. Pugno, Richard N. Zare, Hongkai Wu, Kangning Ren

2023The Innovation22 citationsDOIOpen Access PDF

Abstract

•The monolithic perfluoropolymer surface (MPS) strategy enables biomimetic surfaces to combine geometric-material mechanics with topology-specific superwetting stability.•The theoretical model predicted optimal structures and materials to realize simultaneously superwettability and ultradurability.•The stability of the biomimetic surfaces was extended into a nonlinear range for further improving ultradurability.•The MPS strategy helps to translate bioinspired surface principles into real-world applications. Developing versatile and robust surfaces that mimic the skins of living beings to regulate air/liquid/solid matter is critical for many bioinspired applications. Despite notable achievements, such as in the case of developing robust superhydrophobic surfaces, it remains elusive to realize simultaneously topology-specific superwettability and multipronged durability owing to their inherent tradeoff and the lack of a scalable fabrication method. Here, we present a largely unexplored strategy of preparing an all-perfluoropolymer (Teflon), nonlinear stability-assisted monolithic surface for efficient regulating matters. The key to achieving topology-specific superwettability and multilevel durability is the geometric-material mechanics design coupling superwettability stability and mechanical strength. The versatility of the surface is evidenced by its manufacturing feasibility, multiple-use modes (coating, membrane, and adhesive tape), long-term air trapping in 9-m-deep water, low-fouling droplet transportation, and self-cleaning of nanodirt. We also demonstrate its multilevel durability, including strong substrate adhesion, mechanical robustness, and chemical stability, all of which are needed for real-world applications. Developing versatile and robust surfaces that mimic the skins of living beings to regulate air/liquid/solid matter is critical for many bioinspired applications. Despite notable achievements, such as in the case of developing robust superhydrophobic surfaces, it remains elusive to realize simultaneously topology-specific superwettability and multipronged durability owing to their inherent tradeoff and the lack of a scalable fabrication method. Here, we present a largely unexplored strategy of preparing an all-perfluoropolymer (Teflon), nonlinear stability-assisted monolithic surface for efficient regulating matters. The key to achieving topology-specific superwettability and multilevel durability is the geometric-material mechanics design coupling superwettability stability and mechanical strength. The versatility of the surface is evidenced by its manufacturing feasibility, multiple-use modes (coating, membrane, and adhesive tape), long-term air trapping in 9-m-deep water, low-fouling droplet transportation, and self-cleaning of nanodirt. We also demonstrate its multilevel durability, including strong substrate adhesion, mechanical robustness, and chemical stability, all of which are needed for real-world applications.

Topics & Concepts

DurabilityRobustness (evolution)Materials scienceFoulingNonlinear systemScalabilityNanotechnologyTopology (electrical circuits)FabricationCoatingComputer scienceMechanical engineeringMembraneComposite materialEngineeringElectrical engineeringPhysicsAlternative medicineGeneticsBiochemistryBiologyDatabasePathologyMedicineQuantum mechanicsChemistryGeneSurface Modification and SuperhydrophobicityAdhesion, Friction, and Surface InteractionsFluid Dynamics and Thin Films
All-perfluoropolymer, nonlinear stability-assisted monolithic surface combines topology-specific superwettability with ultradurability | Litcius