Bio-inspired Studies on Adhesion of a Thin Film on a Rigid Substrate electronic resource by Zhilong Peng.
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TextSeries: Springer Theses, Recognizing Outstanding Ph.D. ResearchPublication details: Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 2015Description: XIII, 97 p. 46 illus. online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9783662469552Subject(s): Materials Science | Nanotechnology | Biomaterials | Materials -- Surfaces | Thin films | Materials Science | Surfaces and Interfaces, Thin Films | Nanotechnology and Microengineering | BiomaterialsDDC classification: 620.44 LOC classification: TA418.7-418.76TA418.9.T45Online resources: Click here to access online Introduction -- Extension of the Two-dimensional JKR Theory to the Case With a Large Contact Width -- Peeling Behavior of a Bio-inspired Nano-film with Finite Length on a rigid Substrate -- Effect of Pre-tension on the Peeling Behavior of a Bio-inspired Nano-film and a Hierarchical Adhesive Structure -- Effects of Surface Roughness and Film Thickness on the Adhesion of a Bio-inspired Nano-film -- Effects of the Relative Humidity and Water Droplet on Adhesion of a Bio-inspired Nano-film -- Effect of Geometry on the Adhesive Behavior of Bio-inspired Fibrils -- Conclusion and Future Work.
The thesis systematically investigates the factors which influence many animals’ robust adhesion abilities and micro-reversible adhesion mechanisms, including the geometric principles of their adhesion, relative humidity, surface roughness, and pre-tension. Studies exploring biological adhesion mechanisms are not only of great significance for the design of advanced adhesive materials and adhesion systems for micro-climbing robots, but also very helpful for resolving the problem of adhesion failure in MEMS/NEMS.
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