Title :
In-liquid sensing of chemical compounds by QCM sensors coupled with high-accuracy ACC oscillator
Author :
Ferrari, M. ; Ferrari, V. ; Marioli, D. ; Taroni, A. ; Suman, M. ; Dalcanale, E.
Author_Institution :
Dept. of Electron. & Autom., Brescia Univ., Italy
Abstract :
A novel oscillator circuit with automatic capacitance compensation (ACC) capability has been coupled with QCM sensors coated with quinoxaline and pyrazine bridged cavitands to detected aromatic and chlorinated compounds in water. With double-side immersed 10-MHz crystals coated with the quinoxaline cavitand, the detection of toluene in deionized water was possible down to concentrations of few parts per million. The ACC oscillator advantageously provides the simultaneous measurement of the sensor resonant frequency, damping, and value of the compensated parallel capacitance. This enabled to observe that the analyte sorption in the cavitand coating not only brings about a mass uptake, but also an increase of losses, and, apparently, a rise in the coating average permittivity.
Keywords :
chemical sensors; chemical variables measurement; compensation; crystal resonators; damping; microbalances; oscillators; ACC oscillator; QCM sensors; analyte sorption; aromatic compounds; automatic capacitance compensation; cavitand coating; chlorinated compounds; coating average permittivity; damping; deionized water; in-liquid chemical sensing; oscillator circuit; pyrazine-bridged cavitands; quartz crystal microbalance; quinoxaline cavitand; quinoxaline-bridged cavitands; sensor resonant frequency; toluene detection; Capacitance measurement; Capacitive sensors; Chemical compounds; Chemical sensors; Coatings; Coupling circuits; Crystals; Frequency measurement; Oscillators; Permittivity measurement;
Conference_Titel :
Instrumentation and Measurement Technology Conference, 2004. IMTC 04. Proceedings of the 21st IEEE
Print_ISBN :
0-7803-8248-X
DOI :
10.1109/IMTC.2004.1350985
