Your browser does not support JavaScript!
http://iet.metastore.ingenta.com
1887

access icon free TiN/PECVD-Si3N4/TiN diaphragm-based capacitive-type MEMS acoustic sensor

© The Institution of Engineering and Technology
Received 07/11/2015, Published 08/02/2016
Errata or comment

A capacitive-type MEMS acoustic sensor with a planarised TiN/plasma-enhanced chemical vapour deposition -Si3N4/TiN diaphragm based on a polyimide sacrificial layer is presented. The multi-layer diaphragm has the effective residual stress of +31.5 MPa. Furthermore, this sensor features a 21% lower parasitic capacitance and a 56% lower air-gap resistance in comparison with those of a sensor fabricated without planarisation. Five photomasks were used. In addition, to evaluate the frequency response, both an effective capacitance model and an equivalent circuit model equipped with a voltage-controlled voltage source are newly proposed and compared with conventional models. The open-circuit sensitivity is modelled to −45.4 dBV/Pa at 1 kHz with 9.6 V, indicating a difference of 0.9 dB in comparison with the open-circuit sensitivity of the conventional model.

Inspec keywords: silicon compounds; titanium compounds; masks; plasma CVD; air gaps; acoustic transducers; frequency response; planarisation; microsensors; equivalent circuits; internal stresses; active networks

Other keywords: multilayer diaphragm; capacitance model; plasma-enhanced chemical vapour deposition; voltage-controlled voltage source; TiN-Si3N4-TiN; equivalent circuit model; planarisation; open-circuit sensitivity; parasitic capacitance; frequency response; PECVD; polyimide sacrificial layer; residual stress; photomasks; air-gap resistance; frequency 1 kHz; voltage 9.6 V; diaphragm-based capacitive-type MEMS acoustic sensor

Subjects: Surface treatment (semiconductor technology); Fabrication of MEMS and NEMS devices; Chemical vapour deposition; Lithography (semiconductor technology); Thin film growth, structure, and epitaxy; Sonic and ultrasonic transducers and sensors; Active filters and other active networks; Plasma applications in manufacturing and materials processing; Sensing and detecting devices; Surface treatment and degradation in semiconductor technology; Micromechanical and nanomechanical devices and systems; Chemical vapour deposition

References

    1. 1)
      • 5. Chuang, W.-C., Wang, C.-W., Chu, W.-C., Chang, P.-Z., Hu, Y.-C.: ‘The fringe capacitance formula of microstructures’, J. Micromech. Microeng., 2012, 22, pp. 17.
    2. 2)
    3. 3)
    4. 4)
    5. 5)
    6. 6)
http://iet.metastore.ingenta.com/content/journals/10.1049/el.2015.3856
Loading

Related content

content/journals/10.1049/el.2015.3856
pub_keyword,iet_inspecKeyword,pub_concept
6
6
Loading
Correspondence
This article has following corresponding article(s):
in brief
Print this page
This is a required field
Please enter a valid email address