A Laterally Vibrating Lithium Niobate MEMS Resonator Array Operating at 500C in Air

Abstract

This paper is the first report of the high-temperature characteristics of a laterally vibrating piezoelectric lithium niobate (LiNbO3) MEMS resonator array up to 500C in air. After a high-temperature burn-in treatment, device quality factor (Q) is enhanced to 508 and the resonance shifts to a lower frequency and remains stable up to 500C. During subsequent in situ high-temperature testing, the resonant frequencies of two coupled shear horizontal (SH0) modes in the array are 87.36 MHz and 87.21 MHz at 25C and 84.56 MHz and 84.39 MHz at 500C, correspondingly, representing a -3% shift in frequency over the temperature range. Upon cooling to room temperature, the resonant frequency returns to 87.36 MHz, demonstrating recoverability of device performance. The first- and second-order temperature coefficient of frequency (TCF) are found to be -95.27 ppm/C and 57.5 ppb/C2 for resonant mode A, and -95.43 ppm/C and 55.8 ppb/C2 for resonant mode B, respectively. The temperature-dependent quality factor (Q) and electromechanical coupling coefficient (kt2) are extracted and reported. Device Q decreases to 334 after high-temperature exposure, while kt2 increases to 12.40%. This work supports the use of piezoelectric LiNbO3 as a material platform for harsh environment radio-frequency (RF) resonant sensors (e.g. temperature and infrared).