IES, CNRS, University of Montpellier, 34095 Montpellier, France.
Sensors (Basel). 2023 Mar 20;23(6):3280. doi: 10.3390/s23063280.
An enhanced MEMS capacitive sensor is developed for photoacoustic gas detection. This work attempts to address the lack of the literature regarding integrated and compact silicon-based photoacoustic gas sensors. The proposed mechanical resonator combines the advantages of silicon technology used in MEMS microphones and the high-quality factor, characteristic of quartz tuning fork (QTF). The suggested design focuses on a functional partitioning of the structure to simultaneously enhance the collection of the photoacoustic energy, overcome viscous damping, and provide high nominal capacitance. The sensor is modeled and fabricated using silicon-on-insulator (SOI) wafers. First, an electrical characterization is performed to evaluate the resonator frequency response and nominal capacitance. Then, under photoacoustic excitation and without using an acoustic cavity, the viability and the linearity of the sensor are demonstrated by performing measurements on calibrated concentrations of methane in dry nitrogen. In the first harmonic detection, the limit of detection (LOD) is 104 ppmv (for 1 s integration time), leading to a normalized noise equivalent absorption coefficient (NNEA) of 8.6 ⋅ 10 Wcm Hz, which is better than that of bare Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS), a state-of-the-art reference to compact and selective gas sensors.
用于光声气体检测的增强型 MEMS 电容传感器。这项工作旨在解决集成和紧凑的硅基光声气体传感器文献中缺乏的问题。所提出的机械谐振器结合了 MEMS 麦克风中使用的硅技术的优势和石英音叉 (QTF) 的高品质因数特性。所提出的设计侧重于结构的功能分区,以同时增强光声能量的收集、克服粘性阻尼并提供高标称电容。该传感器使用绝缘体上硅 (SOI) 晶圆进行建模和制造。首先,进行电特性分析以评估谐振器的频率响应和标称电容。然后,在光声激励下并且不使用声腔的情况下,通过对干燥氮气中校准浓度的甲烷进行测量,证明了传感器的可行性和线性度。在第一谐波检测中,检测限 (LOD) 为 104 ppmv(对于 1 s 积分时间),导致归一化噪声等效吸收系数 (NNEA) 为 8.6 ⋅ 10 Wcm Hz,优于最先进的紧凑和选择性气体传感器的石英增强光声光谱 (QEPAS)。
