Title :
Near-field microscopy: Is there an alternative to micro and nano resonating cantilevers?
Author :
Buchaillot, Lionel ; Mairiaux, Estelle ; Walter, Bohme ; Zhuang Xiong ; Faucher, Marc ; Legrand, B. ; Theron, Didier ; Algre, Emmanuelle
Author_Institution :
Inst. d´Electron., de Microelectron. et de, Nanotechnol., IEMN, Villeneuve d´Ascq, France
Abstract :
Most of commercial Atomic Force Microscope (AFM) oscillating probes use micrometric cantilevers that can make measurement with piconewton force resolution under vacuum. However, the flexure vibration cantilevers suffer from a degradation of both resonance frequency and quality factor when operating in liquids. Moreover, the additional laser set-up for amplitude detection also limits the integration and miniaturization of the resonator structure. In order to overcome these difficulties, we propose to replace cantilevers by bulk mode, in-plane vibrating MEMS resonators with integrated transduction methods.
Keywords :
Q-factor; atomic force microscopy; cantilevers; micromechanical resonators; microsensors; nanosensors; amplitude detection; bulk mode; commercial atomic force microscope; flexure vibration cantilevers; in-plane vibrating MEMS resonators; integrated transduction methods; laser set-up; micrometric cantilevers; microresonating cantilevers; miniaturization; nanoresonating cantilevers; near-field microscopy; piconewton force resolution; quality factor; resonance frequency; resonator structure; Atomic force microscopy; Force; Micromechanical devices; Piezoresistance; Probes; Resonant frequency; AFM; laserless; probes; resonators;
Conference_Titel :
Frequency Control Symposium (FCS), 2014 IEEE International
Conference_Location :
Taipei
DOI :
10.1109/FCS.2014.6859928
