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ABSTRACT
Adhesion forces on various surfaces with different hydrophilicity were measured by atomic force microscopy in the force-volume mode and at a location to study the relative humidity (RH) dependence. With an increasing-stable-decreasing trend in RH, the force in the force-volume mode usually exhibits a constant-increase-constant-decrease-constant variation. Surfaces with partial or complete hydrophobicity exhibited a much larger increase compared to a hydrophilic one. However, the behavior on some surfaces was distorted due to a decrease at high stable RHs. Contrastively, the behavior at a location could also display the same behavior. Both gradual and sudden changes were observed at a single location as RH changed. At high stable RHs, the force displayed complex behaviors, indicating unique characteristics at each location. Therefore, the measurement at a location is not suitable to study the RH dependence. Specially, the force measured on silica in the force-volume mode has the mentioned behavior. However, the force at a location can remain stable, gradually/sharply increase or decrease, and suddenly jump or drop with RH. These observations are attributed to the evolution of a water bridge, which is largely influenced by thin-film flow. The findings provide deeper insights into adhesion mechanisms at different RHs.
Acknowledgments
This work was supported by the National Natural Science Foundation of China [Grant number: 51975134].
Disclosure statement
No potential conflict of interest was reported by the author(s).
Supporting information
Characterization of samples and cantilevers; Experimental set-up; Force-displacement curve; Scatter diagram of adhesion forces measured on silica; Scatter diagram of adhesion forces on HOPG, glass, PC, and graphene; Scatter diagram of adhesion forces on silicon (PDF).