Abstract
Capacitive micromachined ultrasound transducers (CMUTs) have broad application prospects in medical imaging, flow monitoring, and nondestructive testing. CMUT arrays are limited by their fabrication process, which seriously restricts their further development and application. In this paper, a vacuum-sealed device for medical applications is introduced, which has the advantages of simple manufacturing process, no static friction, repeatability, and high reliability. The CMUT array suitable for medical imaging frequency band was fabricated by a silicon wafer bonding technology, and the adjacent array devices were isolated by an isolation slot, which was cut through the silicon film. The CMUT device fabricated following this process is a 4 × 16 array with a single element size of 1 mm × 1 mm. Device performance tests were conducted, where the center frequency of the transducer was 3.8 MHz, and the 6 dB fractional bandwidth was 110%. The static capacitance (29.4 pF) and center frequency (3.78 MHz) of each element of the array were tested, and the results revealed that the array has good consistency. Moreover, the transmitting and receiving performance of the transducer was evaluated by acoustic tests, and the receiving sensitivity was −211 dB @ 3 MHz, −213 dB @ 4 MHz. Finally, reflection imaging was performed using the array, which provides certain technical support for the research of two-dimensional CMUT arrays in the field of 3D ultrasound imaging.
Highlights
Ultrasonic technology is widely used in medical diagnosis, underwater detection, and industrial nondestructive testing [1]
The piezoelectric transducer was lectric transducer was selected to emit ultrasound in silicone oil at the same horizontal driven by a waveform generator
We found different reduce the influence of parasitic resistance, the step is to try to use substrate silicon degrees of attenuation on the static capacitance of existing Capacitive micromachined ultrasound transducers (CMUTs) by connecting resistors with lower resistivity or develop some compensation measures on the circuit
Summary
Ultrasonic technology is widely used in medical diagnosis, underwater detection, and industrial nondestructive testing [1]. Piezoelectric ultrasonic transducers still occupy a dominant position in ultrasonic applications [1]. Their acoustic impedance is significantly higher than that of fluid media and air, which significantly limits their performance [9]. To overcome this problem, it is necessary to make corresponding matching layers, which will be used to eliminate excessive reflections on the interface of the two media due to the excessive difference in acoustic impedance [10]
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