Title :
Temperature Dependence of the Elastic Constants of Doped Silicon
Author :
Ng, Eldwin J. ; Hong, Vu A. ; Yushi Yang ; Chae Hyuck Ahn ; Everhart, Camille L. M. ; Kenny, Thomas W.
Author_Institution :
Dept. of Mech. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
Resonators fabricated in heavily doped silicon have been noted to have a reduced frequency-temperature dependence compared with lightly doped silicon. The resonant frequency of silicon microelectromechanical systems (MEMS) resonators is largely governed by the material´s elastic properties, which are known to depend on doping. In this paper, a suite of different types and orientations of resonators were used to extract the first- and second-order temperature dependences of the elastic constants of p-doped silicon up to 1.7e20 cm-3, and n-doped up to 6.6e19 cm-3 . It is shown that these temperature-dependent elastic constants may be used in finite element analysis to predict the frequency-temperature dependence of similarly doped silicon resonators.
Keywords :
doping; elasticity; elemental semiconductors; finite element analysis; micromechanical resonators; silicon; MEMS resonator; Si; finite element analysis; finite element analysis to predict the frequency-temperature; first-order temperature dependence; frequency-temperature dependence; material elastic constant property; microelectromechanical system resonator; p-doped silicon; reduced frequency-temperature dependence; second-order temperature dependence; temperaturedependent elastic constant; Doping; Frequency measurement; Resonant frequency; Silicon; Temperature; Temperature dependence; Temperature measurement; Doping; resonators; silicon; temperature dependence;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2014.2347205
