Detection Methods for Multi-Modal Inertial Gas Sensors

Najar, Fehmi; Ghommem, Mehdi; Kocer, Samed; Elhady, Alaa; Abdel‐Rahman, Eihab

doi:10.3390/s22249688

Cited by 6 publications

(3 citation statements)

References 44 publications

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“…Bistable mechanisms, composed of elastic beams or membranes, are widely employed across various MEMS applications, including microrobotics 36 , switch 37 , resonators 38 , sensors 39,40 , and actuator 41 , owing to their simplicity, low actuation energy, large stroke with small restoring forces, and snap-through behavior. Among these, beam-type bistable mechanisms are particularly prevalent in MEMS as compliant mechanisms, favored for their straightforward structure and negative stiffness properties.…”

Section: Modeling and Design Of The Anti-spring Mechanismmentioning

confidence: 99%

A Miniaturized MEMS Accelerometer with Anti-Spring Mechanism for Enhancing Sensitivity

Wu,

Xiong,

et al. 2024

Preprint

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Anti-spring mechanisms are widely used for improving the noise performance of MEMS accelerometers due to their stiffness softening effect. However, the existing mechanisms typically require large bias force and displacement for achiev¬ing stiffness softening, leading to large device dimensions. Here, we propose a novel anti-spring mechanism composed of two pre-shaped curved beams connected in a parallel configuration, which can achieve stiffness softening without requiring large bias force and displacement. The stiffness softening effect of the mechanism is verified through theoretical modeling and finite element method (FEM) simulation. After that, the mechanism is implemented in a 4.2 mm × 4.9 mm MEMS capacitive accelerometer prototype. The experimental results reveal that the sensitivity of the accelerometer increases by 10.4% compared to the initial sensitivity, at the same time, the noise floor and bias instability decrease by 10.5% and 4.2%. The sensitivity,nonlinearity, bias instability, and noise floor after biasing are 51.1 mV/g, 0.99%, 0.24 mg, and 21.3 μg/√Hz, respectively. Thus, the proposed mechanism can enhance the performance of the accelerometer. This work provides an innovative approach for improving the performance of MEMS accelerometers while enabling miniaturization.

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Section: Modeling and Design Of The Anti-spring Mechanismmentioning

confidence: 99%

A Miniaturized MEMS Accelerometer with Anti-Spring Mechanism for Enhancing Sensitivity

Wu,

Xiong,

et al. 2024

Preprint

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“…Najar et al [24] found that the shifts in the natural frequency and bifurcation location of inertial sensors due to added masses are similar in size. We, therefore, postulate that the threefold difference we observed here is due to the absence of electrostatic fields in experiment # 5 and their presence in experiment # 6.…”

Section: Dynamic Detection Modementioning

confidence: 99%

“…This is attributed to their small size, lightweight, high accuracy, portability, affordability, and their real-time operational capability [1]. Consequently, they found widespread adoption in a multitude of applications, such as pressure sensors [2], temperature sensors [3], force sensors [4], accelerometers [5], gyroscopes [6], and gas sensors [7][8][9][10][11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Unraveling the Nature of Sensing in Electrostatic MEMS Gas Sensors

Shama,

Rahmanian,

Mouharrar

et al. 2023

Preprint

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This paper investigates the fundamental sensing mechanism of electrostatic MEMS gas sensors. It compares among the responsivities of a set of MEMS isopropanol sensors before and after functionalization, and in the presence and absence of electrostatic fields when operated in static and dynamic detection modes. In the static mode, we found that the sensors do not exhibit a measurable change in displacement due to added mass. On the other hand, bare sensors showed a clear change in displacement in response to isopropanol vapor. In the dynamic mode, functionalized sensors showed a measurable frequency shift due to the added mass of isopropanol vapor. In the presence of strong electrostatic fields, the measured frequency shift was found to be threefold larger than that in their absence in response to the same concentration of isopropanol vapor. The enhanced responsivity of dynamic detection allows the sensors to measure the vapor mass captured by the functional material, which is not the case for static detection. The detection of isopropanol by bare sensors in static mode shows that change in the medium permittivity is the primary sensing mechanism. The enhanced responsivity of dynamic mode sensors when operated in strong electrostatic fields shows that their sensing mechanism is a combination of a weaker added mass effect and a stronger permittivity effect. These findings show that electrostatic MEMS gas sensors are independent of the direction of the gravitational field and are, thus, robust to changes in alignment. It is erroneous to refer to them as 'gravimetric' sensors.

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