TY - JOUR
T1 - Effects of multiple wetting incidents, shear and sliding friction on lubricant stability in SLIPS
AU - Niemelä, Henna
AU - Tuominen, Mikko
AU - Koivuluoto, Heli
AU - Vuoristo, Petri
N1 - Funding Information:
H.N. thanks the Tampere University Graduate School for financial support. The FESEM work made use of the Tampere Microscope Center facilities at Tampere University, Tampere, Finland.
Publisher Copyright:
© 2023
PY - 2023/7
Y1 - 2023/7
N2 - Surface icing almost invariably derives from the precursory step of liquid water encountering the surface. Thus, slippery liquid infused porous surfaces, SLIPS, must possess steady wetting durability, and lubricant stability to function as a reliable hydro−/icephobic surface design especially in outdoor applications. Additionally, they should maintain their phobic performance under shear forces, and possess low sliding friction to act as a slippery, multirepellent surfaces. These characteristics are needed in variable applications ranging from moving and rotating blades to steady surfaces, operating in altering climate conditions. More profound durability testing is needed to examine the loss of surface functionality when the lubricant is depleted from the structure via various routes. In addition, the durability tests should be designed to serve the application-related purposes and thus, to reveal performance differences between slippery surfaces for further analysis and targeted end-use development. Here, we tested the wetting durability and stability of SLIPS with multicycle Wilhelmy plate by dipping the surfaces multiple times in water bath. Additionally, we examined the effects of centrifugal and friction-based shear stress to investigate the lubricant depletion from the structure. Tests that measure the durability and the stability of SLIPS designs are in great need in further developing functional slippery surfaces for real outdoor application coatings which encounter environmental stresses, e.g., wetting and icing. Acknowledging the material differences under specific stresses will guide designing the slippery surfaces towards more specific and functionable end-use applications.
AB - Surface icing almost invariably derives from the precursory step of liquid water encountering the surface. Thus, slippery liquid infused porous surfaces, SLIPS, must possess steady wetting durability, and lubricant stability to function as a reliable hydro−/icephobic surface design especially in outdoor applications. Additionally, they should maintain their phobic performance under shear forces, and possess low sliding friction to act as a slippery, multirepellent surfaces. These characteristics are needed in variable applications ranging from moving and rotating blades to steady surfaces, operating in altering climate conditions. More profound durability testing is needed to examine the loss of surface functionality when the lubricant is depleted from the structure via various routes. In addition, the durability tests should be designed to serve the application-related purposes and thus, to reveal performance differences between slippery surfaces for further analysis and targeted end-use development. Here, we tested the wetting durability and stability of SLIPS with multicycle Wilhelmy plate by dipping the surfaces multiple times in water bath. Additionally, we examined the effects of centrifugal and friction-based shear stress to investigate the lubricant depletion from the structure. Tests that measure the durability and the stability of SLIPS designs are in great need in further developing functional slippery surfaces for real outdoor application coatings which encounter environmental stresses, e.g., wetting and icing. Acknowledging the material differences under specific stresses will guide designing the slippery surfaces towards more specific and functionable end-use applications.
KW - Durability
KW - Hydrophobic surfaces
KW - Icephobicity
KW - Lubricant stability
KW - Multicycle Wilhelmy plate
KW - Sliding friction
KW - Slippery liquid infused porous surfaces
KW - Slippery surfaces
KW - Wetting
U2 - 10.1016/j.coldregions.2023.103878
DO - 10.1016/j.coldregions.2023.103878
M3 - Article
AN - SCOPUS:85153523510
SN - 0165-232X
VL - 211
JO - Cold Regions Science and Technology
JF - Cold Regions Science and Technology
M1 - 103878
ER -