Title :
Atomic Resolution Disk Resonant Force and Displacement Sensors for Measurements in Liquid
Author :
Mehdizadeh, Emad ; Rostami, Mohamad ; Xiaobo Guo ; Pourkamali, Siavash
Author_Institution :
Dept. of Electr. Eng., Univ. of Texas at Dallas, Richardson, TX, USA
Abstract :
This letter presents resonant microelectromechanical systems capable of resolving subatomic features and/or measurement of atomic level forces in liquid media (in addition to air/vacuum). It has previously been shown that forces in the micro- and nano-Newton range applied to flexible extensional-mode resonant microstructures can cause significant resonant frequency shifts [1]. In this letter, the same principle has been applied to rotational mode disk resonators that are capable of maintaining relatively high quality factors in liquid. Preliminary results indicate about tenfold improvement in combined displacement-force resolution figure-of-merit compared with typical piezoresistive cantilevers when operating in liquid. Using integrated comb-drive electrostatic actuators, displacement and force resolutions as high as 200 fm and 1 nN, respectively, have been demonstrated. By application of the force through a levering mechanism, force sensitivities in the pN range can be achieved while maintaining sub-nm spatial resolution.
Keywords :
Q-factor; atomic force microscopy; displacement measurement; electrostatic actuators; force measurement; force sensors; micromechanical resonators; microsensors; nanosensors; atomic level force measurement; atomic resolution disk resonant displacement sensor; atomic resolution disk resonant force sensor; displacement measurement; displacement resolution; flexible extensional mode resonant microstructure; force resolution; integrated comb-drive electrostatic actuators; levering mechanism; liquid media; microNewton range; microelectromechanical system; nanoNewton range; quality factor maintainence; resonant frequency shift; rotational mode disk resonator; sub-nm spatial resolution maintainence; subatomic feature; Atomic measurements; Force; Force measurement; Frequency measurement; Liquids; Resonant frequency; Sensors; MEMS resonant force-displacement sensor; atomic force microscopy; atomic force microscopy.; in-liquid measurements;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2014.2331675
