Hostname: page-component-8448b6f56d-xtgtn Total loading time: 0 Render date: 2024-04-23T14:25:38.487Z Has data issue: false hasContentIssue false
  • English
  • Français

MEMS Microresonators for High Temperature Sensor Applications

Published online by Cambridge University Press:  31 January 2011

Dharanipal Doppalapudi ,
Richard Mlcak ,
Jeremie LeClair ,
Patrick Gwynne ,
Jeffrey Bridgham ,
Scott Purchase ,
Martin Skelton ,
Gerald Schultz  and
Harry Tuller
Dharanipal Doppalapudi
Affiliation:
dharani@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Richard Mlcak
Affiliation:
mlcak@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Jeremie LeClair
Affiliation:
jleclair@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Patrick Gwynne
Affiliation:
gwynne@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Jeffrey Bridgham
Affiliation:
bridgham@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Scott Purchase
Affiliation:
purchase@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Martin Skelton
Affiliation:
Skelton@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Gerald Schultz
Affiliation:
schultz@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Harry Tuller
Affiliation:
tuller@bostonms.com, Boston MicroSystems Inc., Woburn, Massachusetts, United States
Get access

Abstract

Microelectromechanical Systems (MEMS) are being extensively investigated as a means of miniaturizing piezoelectric sensors thereby offering higher sensitivity, reduced power consumption, and ability to form compact multi-sensor arrays. Such devices typically employ one or more silicon micromechanical elements (e.g. membranes, cantilever beams and tethered proof masses) driven electromechanically by a polycrystalline piezoelectric film. The use of polycrystalline materials results in inherently less stable and irreproducible device characteristics. For elevated operating temperatures, more robust and refractory materials are also required. In this paper, we describe a MEMS microresonator array capable of operating to temperatures exceeding 600°C enabled by the integration of epitaxially grown piezoelectric AlN films onto single crystal SiC tethered plates. The operation of the microresonators as sensors is illustrated by examining their response to temperature, pressure and chemical analytes.

Keywords

sensorpiezoelectricmicroelectro-mechanical (MEMS)
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1222: Symposium DD – Microelectromechanical Systems — Materials and Devices III , 2009 , 1222-DD01-02
Copyright
Copyright © Materials Research Society 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1 Tuller, H.L. Mlcak, R. Current opinion in solid state & materials science, 3, 501, 1998.Google Scholar
2 Tsubouchi, K. Mikoshiba, N. IEEE Trans. On Sonics and Ultra. Vol. SU-32, p. 634, 1995.Google Scholar
3 Deger, C. Born, E. Angerer, H. Ambacher, O. Stutzmann, M. Hornsteiner, J., Riha, E. Fischerauer, G. Appl. Phys. Lett., 72, 2400, 1998.Google Scholar
4 Cimalla, V. Pezoldt, J. Ambacher, O. J. Phys. D: Appl. Phys. 40 (2007) 63866434.Google Scholar
5 Turner, R.C. Fuierer, P.A. Newnham, R.E. Shrout, T.R. Appl. Acoust. 41 (1994) 299324.Google Scholar
6 Doppalapudi, D. Mlcak, R. Chan, J. Tuller, H. Bhattacharya, A. and Moustakas, T. in GaN and Related Alloys-2003 (MRS Symp. Proc. Vol. 798), pp. 403408, 2004.Google Scholar
7 Doppalapudi, D. Mlcak, R. Chan, J. Tuller, H.L. Abell, J. Li, W. and Moustakas, T.D. State – of-the-Art Program on Compound Semiconductors XLI -and- Nitride and Wide Bandgap Semiconductors for Sensors, Photonics, and Electronics V, Ed. by Ng, H. and Baca, A.G. Proc. Electro.Chem. Soc. meeting Honolulu, pp. 287300, 2004.Google Scholar
8 Mlcak, R. Tuller, H.L. US Patent # 5,338,416, Aug. 16, 1994.Google Scholar
9 Mlcak, R. Tuller, H.L. US Patent # 5,464,509, Nov. 7, 1995.Google Scholar
10 Tuller, H.L. Mlcak, R. Sensors and Actuators B35-36, 1996, p. 255 Google Scholar
11 Doppalapudi, D. Moustakas, T.D. Handbook of Thin Film Materials, ed. Nalwa, H. Vol. 2, pp. 57115, 2001 Google Scholar
12 Mlcak, R. Doppalapudi, D. Chan, J. Sampath, A.V. Moustakas, T.D. Tuller, H.L. The 3rd Intl' Aviation Security Technology Symposium, Nov. 27-30, 2001.Google Scholar