Title :
Piezoresistive geometry for maximizing microcantilever array sensitivity
Author :
Fletcher, Patrick C. ; Xu, Y. ; Gopinath, P. ; Williams, J. ; Alphenaar, B.W. ; Bradshaw, R.D. ; Keynton, R.S.
Author_Institution :
Depts. of Mech. Eng., Univ. of Louisville, Louisville, KY
Abstract :
Our group has focused on the development of piezoresistive cantilevers for gas detection using a nonreaction-based method - viscous damping. This work represents a continuation of this effort by reporting on the development, fabrication and testing of a second generation device consisting of asymmetric piezoresistive cantilevers to maximize device sensitivity. The first mode of resonance, static & dynamic sensitivities, and Q-factors ranged from 40 kHz - 63 kHz, 1-6 Omega/mum & 3-17 Omega/mum, and 1700 - 4200, respectively, depending on piezoresistor geometry and beam length. The redesigned piezoresistive microcantilevers were 15 - 200 times more sensitive than the best symmetric design previously reported by our group.
Keywords :
cantilevers; geometry; micromechanical devices; piezoresistive devices; asymmetric piezoresistive cantilevers; device sensitivity maximization; gas detection; microcantilever array sensitivity; nonreaction-based method; piezoresistive geometry; viscous damping; Chemicals; Computational geometry; Damping; Electrical resistance measurement; Immune system; Leg; Optical resonators; Piezoresistance; Stress measurement; Testing; Piezoresistor; array; cantilever; microcantilever; optimization;
Conference_Titel :
Sensors, 2008 IEEE
Conference_Location :
Lecce
Print_ISBN :
978-1-4244-2580-8
Electronic_ISBN :
1930-0395
DOI :
10.1109/ICSENS.2008.4716751
