posted on 2021-08-10, 21:15authored byHuazhen An, Shuai Wang, Dawei Li, Zhilong Peng, Shaohua Chen
The exceptional adhesive ability
of geckos remains almost uninfluenced
by contaminated surfaces, showing that the adhesion system of geckos
has self-cleaning properties. Although there have been several studies
on the self-cleaning performance of geckos and gecko-inspired synthetic
adhesives, the microscale mechanical mechanism of self-cleaning is
still unclear. In the present study, a micropillar-arrayed surface
is fabricated using a template molding method to investigate its self-cleaning
performance in a load-pull contact process. The effects of preload,
microparticle size on self-cleaning properties are studied. The self-cleaning
efficiency of the micropillar-arrayed surface is found to increase
with an increase in the microparticle size. For large and small microparticles,
self-cleaning efficiency increases with an increase in the preload.
For medium microparticles, self-cleaning efficiency first increases
and then decreases as the preload increases. The mechanical mechanism
underlying such self-cleaning performance is further elucidated; it
is mainly attributed to the competition among the elastic energy stored
in the micropillars induced by the bending deformation, the interfacial
adhesion energy between the microparticles and the deformed micropillars,
and the interfacial adhesion energy between the microparticles and
substrate, as well as the varying contact states between the microparticles
and the deformed micropillars. The preload can not only change the
contact states between the microparticles and the micropillar-arrayed
surface but also influence the bending elastic energy stored in the
micropillars. The results obtained in the present study can help deeply
understand the self-cleaning mechanism of micropillar-arrayed surfaces
as well as provide a guideline for designing functional surfaces with
high self-cleaning efficiency.