Tunable Young's Modulus in Carbon MEMS Using Graphene-Based Stiffeners

• Published in: ECS transactions Vol. 50; no. 12; pp. 423 - 434
• Main Authors: Washburn, Cody M, Lambert, Timothy N., Blecke, Jill, Davis, Danae, Finnegan, Patrick S., Hance, Brad G., Wheeler, David R., Beechem, Thomas E., Alam, Todd M., Brumbach, Michael T., Strong, Jennifer M.
• Format: Journal Article
• Language: English
• Published: The Electrochemical Society, Inc 15.03.2013
• ISSN: 1938-5862; 1938-6737
• DOI: 10.1149/05012.0423ecst

Carbon composite micro-electromechanical systems (C-MEMS) incorporating 2 wt.% graphene stiffeners show a 65% increase in Young's modulus and 11% increase in conductivity. An improved reduced graphene oxide (iRGO), is blended into pyrolytic carbon beams prepared for resonant frequency testing. Designed around a 10:1 (length: width) aspect ratio, the linearity of wt.% iRGO in the cantilevers as a function of resonant frequencies is evaluated. The collection of the 1st through 3rd bending modes using laser doppler velocimetery (LDV) of the graphene filled cantilevers shows an increase in frequency response with nanomaterial loading (wt.%). A model was developed using the 3-bending modes and correlated with cross sectional geometry and density to extract a Young's modulus.