Investigation of Unconventional Cantilevers for Applications in High Speed Atomic Force Microscopy (AFM)
University Of Massachusetts Lowell, Lowell MA
Investigators
Abstract
The objective of this research is to investigate unconventional cantilever cross sections for applications in high speed Atomic Force Microscopy (AFM). High speed AFM is of interest for quality control in nanomanufacturing. The cantilevers will be made via polymer molding technology, with the plastic converted via heat treating to silicon carbide. Methods for making defect free cantilevers with geometries that are difficult if not impossible using the standard manufacturing methods will be investigated. The intellectual merit of this project is an increased understanding of application of preceramic polymers for use in making Micro Electro-Mechanical Systems (MEMS). This work will expand the repertoire of cantilever geometries accessible to MEMS researchers. In addition, it will elucidate the role of thermal conversion conditions in controlling the formation of cracks in this class of materials. These results can be applied to any number of applications for preceramic polymers. The broader impact is to enable the wider use of high speed AFM for quality control in nanomanufacturing as well as allowing detailed imaging of chemical and biological dynamical processes. The combined performance advantages of higher resonant frequency (and thus higher scanning speed) and the ability to make cantilevers using inexpensive molding techniques would be of substantial benefit to the nanomanufacturing, microelectronics, and biomedical industries. The demonstration of a method to easily enable manufacturing of silicon carbide based MEMS would have a significant impact on the competitiveness of the microelectronics industry internationally. Finally, students involved in this project will gain exposure to advanced MEMS fabrication techniques, as well as a unique range of expertise at the intersection of electrical and plastics engineering, physics, chemistry, and materials science. In particular, the development of new perspectives and creative problem solving skills is integral to interdisciplinary research of this nature and will foster student success.
View original record on NSF Award Search →