The nanofabrication of a nanomachined holed structure localized on the free end of a microcantilever is here presented, as a new tool to design micro-resonators with enhanced mass sensitivity. The proposed method allows both for the reduction of the sensor oscillating mass and the increment of the resonance frequency, without decreasing the active surface of the device. A theoretical analysis based on the Rayleigh method was developed to predict resonance frequency, e ective mass, and e ective sti ness of nanomachined holed microresonators. Analytical results were checked by Finite Element simulations, con rming an increase of the theoretical mass sensitivity up to 250%, without altering other gures of merit. The nanomachined holed resonators were vibrationally characterized, and their Q-factor resulted comparable with solid microcantilevers with same planar dimensions.
Resonating Behaviour of Nanomachined Holed Microcantilevers
Gian Carlo Gazzadi;Simone Luigi Marasso;
2015
Abstract
The nanofabrication of a nanomachined holed structure localized on the free end of a microcantilever is here presented, as a new tool to design micro-resonators with enhanced mass sensitivity. The proposed method allows both for the reduction of the sensor oscillating mass and the increment of the resonance frequency, without decreasing the active surface of the device. A theoretical analysis based on the Rayleigh method was developed to predict resonance frequency, e ective mass, and e ective sti ness of nanomachined holed microresonators. Analytical results were checked by Finite Element simulations, con rming an increase of the theoretical mass sensitivity up to 250%, without altering other gures of merit. The nanomachined holed resonators were vibrationally characterized, and their Q-factor resulted comparable with solid microcantilevers with same planar dimensions.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
