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Monolithic miniaturized quartz microbalance array and its application to chemical sensor systems for liquids

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4 Author(s)
Rabe, J. ; Inst. for Microtechnology, Technische Univ. Braunschweig, Germany ; Buttgenbach, S. ; Schroder, J. ; Hauptmann, P.

Reports on the design, fabrication, and application of novel monolithic miniaturized quartz microbalance (QMB) arrays. Up to now almost all reported resonator arrays (often designated as "electronic noses" or "electronic tongues", respectively, dependent on their application) are assembled from single QMBs. We fabricate arrays with up to 36 QMBs on a single AT-cut quartz blank. Mass sensitive devices based on AT-cut quartz resonators are suitable as (bio)chemical sensors. A frequency shift caused by mass accumulation on the sensor surface increases theoretically with f2, hence the detection limits for the application as chemical sensors should be decreased with increasing frequency. Since the quality factor Q of a quartz crystal decreases with f, the frequency stability is reduced, thus limiting mass sensitivity. Arrays with up to four different resonant frequencies on one chip were fabricated for comparing the resonator behavior of the same coating at different frequencies. In another test setup, different layers were sprayed onto an array of microbalances having all the same resonant frequency. This allowed for comparing the different coating behavior under equivalent test conditions.

Published in:

Sensors, 2002. Proceedings of IEEE  (Volume:2 )

Date of Conference:

2002