Title :
Micromechanical "hollow-disk" ring resonators
Author :
Li, Sheng-Shian ; Lin, Yu-Wei ; Xie, Yuan ; Ren, Zeying ; Nguyen, Clark T C
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Michigan Univ., Ann Arbor, MI, USA
Abstract :
A vibrating polysilicon micromechanical "hollow-disk" ring resonator obtained by removing quadrants of material from a solid disk resonator, but purposely leaving intact beams of material to non-intrusively support the structure, has been demonstrated in several vibration modes spanning frequencies from HF (24.4 MHz), to VHF (72.1MHz), to UHF (1.169 GHz), with Q\´s as high as 67,519, 48,048, and 5,846, respectively. Furthermore, the use of notched support attachments closer to actual extensional ring nodal points raises the Q to 14,603 at 1.2 GHz, which is the highest yet achieved past 1 GHz, and which clearly illustrates the utility of notching for substantially higher Q. At 1.2 GHz, a combination of high Q and larger capacitive transducers allows the notched version to achieve an Rx of only 282 kΩ, which is 12X smaller than achieved by previous pure polysilicon surface-micromachined solid disk resonators in the GHz range.
Keywords :
Q-factor; capacitive sensors; elemental semiconductors; micromechanical resonators; microsensors; silicon; vibrational modes; 1.2 GHz; 24.4 MHz to 1.169 GHz; 282 kohm; Q-factor; Si; capacitive transducers; micromechanical hollow disk ring resonators; notched version; polysilicon surface micromachined solid disk resonators; ring nodal points; vibration modes; Circuits; Electrodes; Loss measurement; Micromechanical devices; Optical ring resonators; Q measurement; Radio frequency; Resonator filters; Solids; Transducers;
Conference_Titel :
Micro Electro Mechanical Systems, 2004. 17th IEEE International Conference on. (MEMS)
Print_ISBN :
0-7803-8265-X
DOI :
10.1109/MEMS.2004.1290711
