Author :
Penza, M. ; Anisimkin, V.I. ; Vasanelli, L.
Abstract :
A SAW delay line, without any absorbent film between the interdigital transducers, has been developed as a thermal gas detector. The change of the thermal conductivity of the ambient atmosphere produces a change of substrate temperature thereby causing a SAW phase variation (SAW response) at the output of the device. Different effects contribute to the SAW response such as the thermal conductivity Δλ, flow rate Δu, dynamic viscosity Δμ, and the density Δρ of the test ambient and they are numerically analysed for each test gas. Uncoated SAW delay lines operating at 41-263 MHz are implemented on SiO2, LiNbO3, Bi12 GeO20, and Bi12SiO20 substrates. The gases under test (H2, He, Ar, CH4, NH3 , N2, O2, dry air) are used within concentrations of 0.1-100% and flow rates of 50-2000 mL/min at 20-150°C and atmospheric pressure. The SAW response Δφ/φ, is measured as function of Δλ, Δu, operating temperature, and gas concentration. The SAW prototype has a good sensitivity: Δφ/φ≡15 ppm to 0.7% CH4 in N2 for a Bi12SiO20 delay line heated at 120°C; Δφ/φ≡15 ppm to 0.4% NH3 in N2 for a YZ-LiNbO3 delay line heated at 120°C. Some selective SAW gas responses are discussed
Keywords :
gas sensors; interdigital transducers; surface acoustic wave delay lines; surface acoustic wave sensors; thermal conductivity; 120 degC; 20 to 150 degC; 41 to 263 MHz; Bi12GeO20; Bi12SiO20; LiNbO3; SAW gas responses; SAW phase variation; SAW response; SiO2; ambient atmosphere; atmospheric pressure; density; dynamic viscosity; flow rate; gas concentration; interdigital transducers; operating temperature; sensitivity; substrate temperature; substrates; thermal conductivity; thermal gas detector; uncoated SAW delay lines; Atmosphere; Bismuth; Delay lines; Gas detectors; Substrates; Surface acoustic waves; Temperature; Testing; Thermal conductivity; Transducers;
