aluminum nitride mems fabrication In this work, we designed a novel structure to produce vibration sensors with a linear voltage output that are suitable for large-amplitude vibration applications. Specifically, the sensor structure featured a cylindrical proof mass attached to a .
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X-ray diffraction (XRD) (D8 Discover Hybrid/S, Bruker Co., Ltd.) was employed to measure the crystalline quality and crystallographic orientation of the grown piezoelectric AlN crystals. The XRD analysis was performed using a 100-mA current and 50-kV working voltage. Figure 4 shows the rocking curve . See moreFigure 6a shows the SEM image of a typical vibration sensor structure. The vibration sensor featured a diaphragm structure that surrounded the flat cylinder-shaped . See more
The fabricated sensors were evaluated for their responses in the sweeping frequency domain from 3000 to 8000 Hz. Figure 7 shows the resonant peaks of . See more
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Finally, field measurements were performed under a relatively large vibration amplitude. To this end, an industrial shaker (F-Series, EMIC corporation) was used to . See more Aluminum nitride (AlN) is a technologically relevant material that can be deposited at low temperatures in the form of thin-films while preserving most of its physical properties. . In this work, we designed a novel structure to produce vibration sensors with a linear voltage output that are suitable for large-amplitude vibration applications. Specifically, the sensor structure featured a cylindrical proof mass attached to a . Aluminum nitride (AlN) is a technologically relevant material that can be deposited at low temperatures in the form of thin-films while preserving most of its physical properties. Consequently, it is widely adopted in microelectromechanical systems (MEMS), especially in acoustic wave devices (RF filters), optoelectronics, sensors and energy .
Abstract: Wafer-level thin-film packaging offers high yield, low cost and small packaging size and can be easily integrated into components within microelectromechanical systems (MEMS). In this work, a fabrication process of thin-film encapsulation (TFE) with aluminum nitride/molybdenum cap is proposed for the packaging of film bulk acoustic .
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This paper presents a micro-electro-mechanical systems (MEMS) processing technology for Aluminum Nitride (AlN) Lamb-wave resonators (LWRs). Two LWRs with different frequencies of 402.1 MHz and 2.097 GHz by varying the top interdigitated (IDT) periods were designed and fabricated. Aluminum nitride is adopted as the material for both the structural layer and the piezoelectric layer; this simplifies the fabrication process and improves the quality factor of the resonator. Both in-plane and out-of-plane flexural modes were investigated.
This article reports on the state-of-the-art of the development of aluminum nitride (AlN) thin-film microelectromechanical systems (MEMS) with particular emphasis on acoustic devices for radio frequency (RF) signal processing. We developed the technological protocol to realize a piezoelectric transducer composed by a Molybdenum (Mo) top electrode, the Aluminum Nitride active layer and a Mo bottom electrode on a polymeric tape.
In this paper, a piezoelectric MEMS resonator is presented working as laterally vibrating resonator. The device is microfabricated with the SOI silicon wafer and piezoelectric aluminum nitride (A1N) thin films.
Amongst the piezoelectric thin films suited for microelectromechanical systems (MEMS), AlN has gained particular technological relevance due to its unique material properties (large bandgap, high dielectric strength, resistivity, thermal conductivity, elastic modulus, and acoustic velocity), sufficient piezoelectric coefficients, and compatibili.After presenting the possible MEMS-CMOS integration strategies, recent demonstrations of AlN-based devices are reviewed, namely energy harvesters, film bulk acoustic resonators (FBAR), contour mode resonators (CMR), gas sensors, imagers, microphones, transducers for chip-scale communication and calorimetric sensors.
In this work, we designed a novel structure to produce vibration sensors with a linear voltage output that are suitable for large-amplitude vibration applications. Specifically, the sensor structure featured a cylindrical proof mass attached to a .
Aluminum nitride (AlN) is a technologically relevant material that can be deposited at low temperatures in the form of thin-films while preserving most of its physical properties. Consequently, it is widely adopted in microelectromechanical systems (MEMS), especially in acoustic wave devices (RF filters), optoelectronics, sensors and energy . Abstract: Wafer-level thin-film packaging offers high yield, low cost and small packaging size and can be easily integrated into components within microelectromechanical systems (MEMS). In this work, a fabrication process of thin-film encapsulation (TFE) with aluminum nitride/molybdenum cap is proposed for the packaging of film bulk acoustic . This paper presents a micro-electro-mechanical systems (MEMS) processing technology for Aluminum Nitride (AlN) Lamb-wave resonators (LWRs). Two LWRs with different frequencies of 402.1 MHz and 2.097 GHz by varying the top interdigitated (IDT) periods were designed and fabricated.
Aluminum nitride is adopted as the material for both the structural layer and the piezoelectric layer; this simplifies the fabrication process and improves the quality factor of the resonator. Both in-plane and out-of-plane flexural modes were investigated. This article reports on the state-of-the-art of the development of aluminum nitride (AlN) thin-film microelectromechanical systems (MEMS) with particular emphasis on acoustic devices for radio frequency (RF) signal processing.
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We developed the technological protocol to realize a piezoelectric transducer composed by a Molybdenum (Mo) top electrode, the Aluminum Nitride active layer and a Mo bottom electrode on a polymeric tape.In this paper, a piezoelectric MEMS resonator is presented working as laterally vibrating resonator. The device is microfabricated with the SOI silicon wafer and piezoelectric aluminum nitride (A1N) thin films. Amongst the piezoelectric thin films suited for microelectromechanical systems (MEMS), AlN has gained particular technological relevance due to its unique material properties (large bandgap, high dielectric strength, resistivity, thermal conductivity, elastic modulus, and acoustic velocity), sufficient piezoelectric coefficients, and compatibili.
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