posted on 2018-03-06, 00:00authored byMuhammad Yunusa, Guillermo J. Amador, Dirk-M. Drotlef, Metin Sitti
The
wrinkling and interfacial adhesion mechanics of a gallium-oxide
nanofilm encapsulating a liquid-gallium droplet are presented. The
native oxide nanofilm provides mechanical stability by preventing
the flow of the liquid metal. We show how a crumpled oxide skin a
few nanometers thick behaves akin to a highly bendable elastic nanofilm
under ambient conditions. Upon compression, a wrinkling instability
emerges at the contact interface to relieve the applied stress. As
the load is further increased, radial wrinkles evolve, and, eventually,
the oxide nanofilm ruptures. The observed wrinkling closely resembles
the instability experienced by nanofilms under axisymmetric loading,
thus providing further insights into the behaviors of elastic nanofilms.
Moreover, the mechanical attributes of the oxide skin enable high
surface conformation by exhibiting liquid-like behavior. We measured
an adhesion energy of 0.238 ± 0.008 J m–2 between
a liquid-gallium droplet and smooth flat glass, which is close to
the measurements of thin-sheet nanomaterials such as graphene on silicon
dioxide.