Surface interactions play an important role in many engineering phenomena as well as in everyday life. Recently, the study of engineering surfaces and interfaces has become the subject of major research in the emerging field of nanotechnology. In this research, interface studies are performed on the nanoscale in two different nanotechnology fields with industrial applications: nanotribology of a microdevice and biomimetics of a floating water fern.
Integrated microprojectors are being developed to project a large image on any surface chosen by users. For a laser-based microprojector, a piezo-electric based adaptive optics unit is adopted in the green laser architecture. Nanolubrication of adaptive optics sliding components is needed to reduce friction and for stick-slip motion. Previous studies of the role of lubricant film thickness in nanolubrication of sliding components in adaptive optics have been carried out in an academic, coupon level fashion and need to be carried out on a device level in order to characterize the role of lubricant film thickness in an actual working device. In this paper, the effect that operating temperatures have on lubricant film thickness, adhesive force and coefficient of friction of used devices is investigated. The results and associated mechanisms are presented and compared with previous coupon level tests to show that the proposed AFM measurement techniques can be employed in other micro devices in which adhesion, film thickness, and coefficient of friction measurements are of interest.
In the emerging field of biomimetics, one can take inspiration from nature and mimic it in order to create various products, devices and structures. There are a large number of objects, including bacteria, plants, land and aquatic animals and seashells, with properties of commercial interest. The subject of interest for this biomimetics research is the water fern Salvinia molesta because of its ability to trap air. Air-retaining surfaces are of technological interest due to their ability to reduce drag when used for fluid transport, ship coatings and other submersible industrial products in which drag is a concern. The purpose of this research is to mimic the air trapping ability of S. molesta in order to prove that a structure can be created in the lab that can mimic the behavior of the fern as well as demonstrate microfabrication techniques that can be utilized in industry to produce such materials. In this work, a novel methodology for the fabrication of microstructures that mimic the water-pinning and air-trapping ability of S. molesta is introduced. Water contact angle, water roll angle and adhesive force of the new microstructure and water fern are investigated.