2022
DOI: 10.3390/s22208082
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Improving the Sensing Properties of Graphene MEMS Pressure Sensor by Low-Temperature Annealing in Atmosphere

Abstract: The high demand for pressure devices with miniaturization and a wide bearing range has encouraged researchers to explore new high-performance sensors from different approaches. In this study, a sensitive element based on graphene in-plane compression properties for realizing pressure sensing is experimentally prepared using microelectromechanical systems (MEMS) fabrication technology; it consists of a 50 µm thick, 1400 µm wide square multilayer component membrane and a graphene monolayer with a meander pattern… Show more

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Cited by 4 publications
(4 citation statements)
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“…To obtain the strain under specific differential pressure, FEA was used to simulate the deformation of the SiN x membrane under the differential pressure, and the corresponding average stress can be calculated (figure 3(b)). By fitting the experiment data shown in figure 3(b), we obtain a GF of −43.3, which is ten times larger than that of some reported graphenes (GF = 0.8 ∼ 4.4) [12,15,26,34] and several times larger than some reported polycrystalline silicon films (GF = 8.8 ∼ 22) [35][36][37].…”
Section: Gauge Factor Sensitivity and Stability Of The Devicementioning
confidence: 53%
See 1 more Smart Citation
“…To obtain the strain under specific differential pressure, FEA was used to simulate the deformation of the SiN x membrane under the differential pressure, and the corresponding average stress can be calculated (figure 3(b)). By fitting the experiment data shown in figure 3(b), we obtain a GF of −43.3, which is ten times larger than that of some reported graphenes (GF = 0.8 ∼ 4.4) [12,15,26,34] and several times larger than some reported polycrystalline silicon films (GF = 8.8 ∼ 22) [35][36][37].…”
Section: Gauge Factor Sensitivity and Stability Of The Devicementioning
confidence: 53%
“…In this study, we report a highly sensitive MEMS differential pressure sensor based on a transfer-free ultrathin 2D PdSe 2 film, which is synthesized on a SiN x diaphragm by plasma-enhanced metal selenization (PES) at low temperature down to 200 °C. It can reach a sensitivity of 3.9 × 10 −4 kPa −1 at a differential pressure range of 0-60 kPa, which is better than the most currently reported 2D diaphragm pressure sensors [12,15,26]. Furthermore, based on a Wheatstone bridge circuit, the device can compensate for the temperature drift and keep excellent pressure monitoring capability.…”
Section: Introductionmentioning
confidence: 96%
“…But, the interface between flexible substrates and 1D materials, however, is not sufficiently strong, which affects the stability of the pressure sensors. As a result, extra treatments, like thermal annealing, are needed to improve the performance [32]. Therefore, in order to avoid additional treatment processes, 2D material, graphene, is used that can offer a large contact area with the substrate [33].…”
Section: Introductionmentioning
confidence: 99%
“…to identify single-layer graphene and probe the key physical properties of its distinctive G, D and 2D peaks (around 1580 cm −1 , 1360 cm −1 and 2700 cm −1 , respectively [16][17][18][19][20][21][22]). The G peak corresponds to the E 2g phonon at the Brillouin zone (BZ) center, reflecting the layer of graphene.…”
Section: Introductionmentioning
confidence: 99%