Abstract:

Plant of carnivorous genus Nepenthes alata has evolved specific pitchers to prey insects for survival in the barren habitat, especially its slippery zone. The excellent slippery function has received considerable interest because of its potential applica-tion in antifriction surface design. The surface morphologies of intact and de-waxed slippery zones were characterized using  scanning electron microscope and scanning white-light interferometer. Hierarchical structures with anisotropic micro- lunate structure and nano- wax crystals were found on the slippery zone. Due to the hierarchical structures, the slippery zone is hy-drophobic. It shows a significant anisotropic wettability with static contact angles 153.3? and 140.1? in the directions perpen-dicular and parallel to the upward direction (toward the peristome), respectively. The sliding angles are ~3? and ~10? in the downward and upward directions, respectively. Crawling experiments indicate that the microscopic surface roughness and the brittleness of the wax crystals may reduce insect attachment in different modes according to the insect mass differences. Moreover, artificial slippery surfaces inspired by the slippery zone of Nepenthes alata were fabricated. Traction experiments quantitatively verified that the friction force of replicated lunate structures with Ra-2.54 ?m surface roughness was reduced by about 25% as compared to flat surface with Ra-0.56 ?m surface roughness for cricket claws.

Key words: biomimetic surface, anisotropic wettability, antifriction, slippery surface, Nepenthes alata