Title :
A wafer-bonded silicon load cell operating in the tensioned-wire regime
Author :
Nikolich, A.D. ; Senturia, S.D.
Author_Institution :
Microsyst. Technol. Labs., MIT, Cambridge, MA, USA
Abstract :
The authors have used wafer-bonding techniques to fabricate a dielectrically isolated single-crystal silicon version of a dual-port, H-shaped resonant load cell operating in the tensioned-wire regime. The typical geometry reported here is 1.1 mu m thick and has four 1200 mu m long tethers connected at their center by a cross-bar. The resonators are made of p/sup +/ single-crystal silicon which has been determined to be under a net tensile strain of 260 p.p.m. The high length-to-thickness ratio of the resonator, combined with high strain, yield a gage factor which approaches that of a tensioned wire, namely 1/2 epsilon , where epsilon is the strain. In this limit, the gage factor is essentially independent of geometry, and solely dependent on the residual strain in the p+ silicon. It may be possible to take advantage of this tensioned-wire regime to achieve highly repeatable gage factors even in the presence of small geometric variations between devices.<>
Keywords :
electric sensing devices; elemental semiconductors; integrated circuit technology; micromechanical devices; resonators; semiconductor technology; silicon; wafer bonding; 1.1 micron; H-shaped resonant load cell; IC technology; Si; dual-port; frequency response; p/sup +/-Si; residual strain; resonators; semiconductor technology; tensioned-wire; wafer-bonding; Capacitive sensors; Geometry; Isolation technology; Leg; Magnetic resonance; Magnetic sensors; Molecular beam epitaxial growth; Piezoresistance; Resonant frequency; Silicon;
Conference_Titel :
Solid-State Sensor and Actuator Workshop, 1992. 5th Technical Digest., IEEE
Conference_Location :
Hilton Head Island, SC, USA
Print_ISBN :
0-7803-0456-X
DOI :
10.1109/SOLSEN.1992.228302
