Temperature Compensated Bulk-Mode Capacitive MEMS Resonators With ±16 ppm Temperature Stability Over Industrial Temperature Ranges.

This letter reports temperature compensated single crystal silicon (SCS) bulk-mode capacitive microelectromechanical system (MEMS) resonators with high temperature stability of less than ±20 ppm over industrial temperature range. Degenerate doping is adopted to change the temperature coefficient of frequency ($TCF$) and adjusting of crystal orientation is implemented to tune the turnover points for the MEMS resonators, thanks to the different temperature coefficient of elastic constants ($TCE$) of the resonators along different crystal orientation. The adjustment effects are verified by using finite element method (FEM) simulations as well as measurement results. Two bulk-modes, namely length-extensional (LE) and square-extensional (SE) mode resonators along various crystal orientations in a degenerate-doped (100) SCS wafer are designed and fabricated. The measurement frequency shifts are approximately ±20 ppm for the LE mode resonator and ±16 ppm for the SE mode resonator as the resonators are placed along 22.5° from the <110> direction over industrial temperature range of −40°C to 85 °C, respectively. It highlights an effective way to reduce the $TCF$ via degenerate doping and precisely adjust the turnover point by crystal orientation tuning for MEMS resonators. [2022-0046] [ABSTRACT FROM AUTHOR]