Title :
A low-power gas sensor for environmental monitoring using a capacitive micromachined ultrasonic transducer
Author :
Mahmud, M.M. ; Li, J. ; Lunsford, J.E. ; Zhang, X. ; Yamaner, F.Y. ; Nagle, H.T. ; Oralkan, O.
Author_Institution :
Dept. of Electr. & Comput. Eng., North Carolina State Univ., Raleigh, NC, USA
Abstract :
We present a low-power gas sensor design based on a capacitive micromachined ultrasonic transducer (CMUT), for use on self-powered wearable platforms. Earlier a CMUT-based sensor, with 70-mW power consumption operating at 50 MHz, achieved ppt-level detection limit for chemical warfare agents. In this work we present a sensor operating at 4.33 MHz and consuming 0.77 mW for environmental monitoring. The sensor comprises a polymer-functionalized CMUT resonator in the feedback loop of a Colpitts oscillator. We fabricated the CMUT resonators using a novel process based on anodic bonding. The cavities and bottom electrodes are formed on a borosilicate glass wafer. The device layer of an SOI wafer bonded on glass forms the vibrating plate on top of vacuum-sealed cavities. This fabrication approach reduces process complexity and helps minimize parasitic components. CMUTs with center frequencies in the 3-50 MHz range with Q-factors as high as ~400 have successfully been fabricated. We used a 4.52-MHz device (Q=180) coated with a thin layer of polyisobutylene (PIB) for sensor demonstration.
Keywords :
Q-factor; borosilicate glasses; capacitive transducers; environmental monitoring (geophysics); gas sensors; micromachining; micromechanical resonators; microsensors; oscillators; polymer films; silicon-on-insulator; thin film sensors; ultrasonic bonding; ultrasonic transducers; CMUT-based sensor; Colpitts oscillator; Q-factors; SOI wafer; anodic bonding; borosilicate glass wafer; capacitive micromachined ultrasonic transducer; chemical warfare agents; environmental monitoring; fabrication approach; feedback loop; frequency 3 MHz to 50 MHz; frequency 4.33 MHz; frequency 4.52 MHz; frequency 50 MHz; low-power gas sensor design; parasitic component minimization; polymer functionalized CMUT resonator; power 0.77 mW; power 70 mW; ppt-level detection limit; self-powered wearable platforms; thin film polyisobutylene; vacuum sealed cavity; vibrating plate; Bonding; Cavity resonators; Chemicals; Electrodes; Oscillators; Resonant frequency; Ultrasonic transducers; anoding bonding; capacitive micromachined ultrasonic transducer; environmental monitoring; low-power; massloading;
Conference_Titel :
SENSORS, 2014 IEEE
Conference_Location :
Valencia
DOI :
10.1109/ICSENS.2014.6985089
