access icon free Micro-electro-mechanical systems capacitive ultrasonic transducer with a higher electromechanical coupling coefficient

© The Institution of Engineering and Technology
Received 18/05/2015, Accepted 07/08/2015, Published

Since the proposing of capacitive micromachined ultrasonic transducer by Khuri Yakub group in 1994 that this kind of transducer occupying the advantages of wide bandwidth, impedance matching well with the propagation medium especially in fluid and air and high sensitivity, has shown a great potential for wide ranges of applications. This Letter reports kind of micro-electro-mechanical systems (MEMS) capacitive ultrasonic transducer with the novel cavities embedded in the device layer of silicon on insulator wafer bonded with a glass substrate. The optimum geometric dimensions are confirmed by both mechanical vibrating of the membrane and the electrical characteristics analysis. Finite-element analysis is adopted to determine the operation mode. The safety and reliability of the proposed device is ensured by the obtained deflections and equivalent stress under operation/collapse voltage. The bottom electrodes of the proposed transducer are fabricated on the top surface of the glass substrate. The parallel parasitic capacitance is reduced, thus improving the electromechanical coupling coefficient. The test results show that the electromechanical coupling coefficient is 69.65%, which demonstrates that this proposed MEMS capacitive ultrasonic transducer structure can enhance the performance significantly.

Inspec keywords: elemental semiconductors; silicon-on-insulator; vibrations; ultrasonic transducers; capacitance; capacitive transducers; electromechanical effects; wafer bonding; reliability; micromachining; membranes; silicon; finite element analysis; micromechanical devices

Other keywords: device safety; microelectromechanical system capacitive ultrasonic transducer; operation-collapse voltage; finite-element analysis; operation mode; parallel parasitic capacitance; membrane mechanical vibration; device reliability; optimum geometric dimensions; Si; glass substrate surface; propagation medium; wafer bonding; electrical characteristics; electromechanical coupling coefficient; silicon on insulator; equivalent stress; impedance matching; SiO2; capacitive micromachined ultrasonic transducer; bottom electrodes

Subjects: Sonic and ultrasonic transducers and sensors; Micromechanical and nanomechanical devices and systems; Fabrication of MEMS and NEMS devices; Transducers; Design and modelling of MEMS and NEMS devices; Reliability

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