Title :
Second order temperature compensated piezoelectrically driven 23 MHz heavily doped silicon resonators with ±10 ppm temperature stability
Author :
Jaakkola, Antti ; Pekko, Panu ; Dekker, James ; Prunnila, Mika ; Pensala, Tuomas
Author_Institution :
VTT Tech. Res. Centre of Finland, Espoo, Finland
Abstract :
We report quartz level temperature stability of piezoelectrically driven silicon MEMS resonators. Frequency stability of better than ±10 ppm is measured for 23 MHz extensional mode resonators over a temperature range of T = -40 ... + 85°C. The temperature compensation mechanism is entirely passive, relying on the tailored elastic properties of heavily doped silicon with a doping level of n > 1020cm-3, and on an optimized resonator geometry. The result highlights the potential of silicon MEMS resonators to function as pin-to-pin compatible replacements for quartz crystals without any active temperature compensation.
Keywords :
crystal resonators; doping profiles; elemental semiconductors; frequency stability; heavily doped semiconductors; micromechanical resonators; silicon; Si; doping level; elastic properties; extensional mode resonators; frequency 23 MHz; frequency stability; heavily doped silicon resonators; optimized resonator geometry; piezoelectrically driven silicon MEMS resonators; quartz level temperature stability; temperature compensation mechanism; Frequency measurement; Micromechanical devices; Resonant frequency; Silicon; Temperature; Temperature measurement; Thermal stability;
Conference_Titel :
Frequency Control Symposium & the European Frequency and Time Forum (FCS), 2015 Joint Conference of the IEEE International
Print_ISBN :
978-1-4799-8865-5
DOI :
10.1109/FCS.2015.7138871
