Journal
IEEE TRANSACTIONS ON ULTRASONICS FERROELECTRICS AND FREQUENCY CONTROL
Volume 68, Issue 11, Pages 3423-3429Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TUFFC.2021.3092831
Keywords
Crystals; Resonant frequency; Q-factor; Attenuation; Temperature measurement; Electrodes; Apertures; Acoustic attenuation; catangasite; High overtone Bulk Acoustic wave Resonator (HBAR); microwave frequencies
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Funding
- Deutsche Forschungsgemeinschaft (DFG) [SO 1085/2-2, FR 1301/21-2]
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This study explores the special material properties of the single crystalline material CTGS and its suitability for microacoustic applications under extreme conditions. The crystal structure's high degree of order and acceptable piezoelectric strength make it a potential candidate for use at high temperatures. Investigation into the crystal's behavior at gigahertz frequencies reveals low-loss dynamic behavior and the predominant Akhiezer loss mechanism.
This article presents a study of special material properties of the single crystalline material Ca3TaGa3Si2O14 (CTGS = Catangasite). The comparatively highly ordered crystal structure and acceptable piezoelectric strength make it a candidate for microacoustic applications under extreme conditions. Obviously, low-loss dynamic behavior is typical for this crystal which consequently enables high-temperature use. As a particular challenge, the behavior at gigahertz frequencies is investigated here. For that, High overtone Bulk Acoustic wave Resonator (HBAR) type measurements in the range of 1-6 GHz are performed. The selection of five distinctive propagation directions for exclusively pure or quasi-longitudinal modes enables to derive the dynamic viscosities from the quality factors of HBAR results. The observed frequency dependences exhibit Akhiezer behavior as the predominant loss mechanism in the cases examined.
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