Temperature-compensated SH-APM sensors: new theoretical and experimental results

Author

Déjous, C. ; Esteban, I. ; Rebière, D. ; Pistré, J. ; Planade, R.

Author_Institution

Bordeaux I Univ., Talence, France

fYear

1997

fDate

28-30 May 1997

Firstpage

163

Lastpage

168

Abstract

Our aim is to study acoustic wave devices for sensing applications in gas or liquid media. Compared to surface acoustic wave (SAW) devices, shear horizontal acoustic plate mode (SH-APM) devices are based on thin piezoelectric plates, so that a great number of stationary waves, or plate modes, can propagate. SH-APM devices present two main advantages. Firstly, they are able to work in a liquid medium without excessive acoustic loss. Secondly, they can work in an aggressive medium, by using the unmetallized quartz surface for detection. As temperature variation is a critical parameter, it is important to know the device behaviour with temperature. This was already achieved for SAW devices, and it has been done partially for SH-APM devices. In this paper, we propose to recall main theoretical results, and to use the model approach to study particular SH-APM devices, from a theoretical and an experimental point of view

Keywords

chemical sensors; crystal oscillators; piezoelectric transducers; SH-APM sensors; aggressive medium; plate modes; shear horizontal acoustic plate mode (SH-APM) devices; stationary waves; temperature variation; thin piezoelectric plates; unmetallized quartz surface; Acoustic devices; Acoustic propagation; Acoustic transducers; Acoustic waves; Chemical sensors; Piezoelectric transducers; Substrates; Surface acoustic wave devices; Surface acoustic waves; Temperature sensors;

fLanguage

English

Publisher

ieee

Conference_Titel

Frequency Control Symposium, 1997., Proceedings of the 1997 IEEE International

Conference_Location

Orlando, FL

Print_ISBN

0-7803-3728-X

Type

conf

DOI

10.1109/FREQ.1997.638538

Filename

638538