Modeling and Design Parameter Optimization to Improve the Sensitivity of a Bimorph Polysilicon-Based MEMS Sensor for Helium Detection

Authors

Sulaiman Mohaidat, University of Nebraska-LincolnFollow
F. M. Alsaleem, University of Nebraska-LincolnFollow

Document Type

Article

Date of this Version

6-1-2024

Citation

Mohaidat, S.; Alsaleem, F. Modeling and Design Parameter Optimization to Improve the Sensitivity of a Bimorph Polysilicon- Based MEMS Sensor for Helium Detection. Sensors 2024, 24, 3626. https://doi.org/10.3390/s24113626

Comments

Open access.

Abstract

Helium is integral in several industries, including nuclear waste management and semiconductors. Thus, developing a sensing method for detecting helium is essential to ensure the proper operation of such facilities. Several approaches can be used for helium detection, including based on the high thermal conductivity of helium, which is several times higher than air. This work utilizes the high thermal conductivity of helium to design and analyze a bimorph MEMS sensor for helium sensing applications. COMSOL Multiphysics software (version 6.2) is used to carry out this investigation. The sensor is constructed from poly-silicon and SiO₂ materials with a trenched cantilever beam configuration. The sensor is electrically heated, and its morphed displacement depends on the surrounding gas’s composition, which decreases in the presence of helium. Several factors were investigated to probe their effect on the sensor’s sensitivity to helium, including the thickness of the poly-silicon layer, the configuration of the trench, and the thickness and location of SiO₂ layer. The simulations showed that the best performance, up to 2 ppm helium detection level, can be achieved with thinner beams and medium trench lengths.