Abstract
In this paper, mathematical modeling and simulation of a MEMS-based clamped square-shape membrane for capacitive pressure sensors have been performed. Three types of membrane materials were investigated (i.e. Zinc Oxide (ZnO), Zinc Sulfide (ZnS) and Aluminum Nitride (AlN)). Various performance parameters such as capacitance changes, deflection, nonlinearity, the sensitivity of the membrane structure for different materials and film-thicknesses have been considered using the Finite Element Method (FEM) and analytically determined using the FORTRAN environment. The simulation model outperforms in terms of the effective capacitance value. The results show that the membrane deflection is linearly related to the applied pressure. The ZnS membrane provides a capacitance of 0.023 pico-Farad at 25 kPa with a 42.5% relative capacitance changes to reference capacitance. Additionally, the results show that for ZnO and AlN membranes the deflection with no thermal stress is higher than that with thermal stress. However, an opposite behavior for the ZnS membrane structure has been observed. The mechanical and capacitance sensitivities are affected by the membrane thickness as the capacitance changes are inversely proportional to the membrane thickness. Such results open possibilities to utilize various materials for pressure sensor applications by means of the capacitance-based detection technique.
Highlights
Pressure sensors have been receiving significant attention due to their potential for a variety of applications including the touch-sensitive on flexible displays [1,2], health-care condition monitoring [3], soft robotics [4], energy harvesting [5,6] and electronic skin [7,8]
The results show that elliptical-shaped capacitive pressure sensors have shown better linearity compared with the circular-membrane pressure sensor
This paper proposes a design of a MEMS-based capacitive pressure sensor with clamped square membrane utilizing three types of membrane materials; zinc oxide
Summary
Pressure sensors have been receiving significant attention due to their potential for a variety of applications including the touch-sensitive on flexible displays [1,2], health-care condition monitoring [3], soft robotics [4], energy harvesting [5,6] and electronic skin [7,8]. Based on the transduction mechanism, pressure sensors can be mainly categorized into piezoelectric, piezoresistive and capacitive types [9]
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