Optimization of LiNbO3/Quartz Substrate for High-Frequency Wideband SAW Devices Using Longitudinal Leaky Waves

Multilayered structures can successfully replace single crystal substrates in high-performance surface acoustic wave (SAW) devices. A combination of high propagation velocity and strong piezoelectric coupling is required for acoustic modes used in wideband high-frequency SAW devices. These character...

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Bibliographic Details
Published in:IEEE transactions on ultrasonics, ferroelectrics, and frequency control ferroelectrics, and frequency control, 2020-07, Vol.67 (7), p.1485-1491
Main Author: Naumenko, Natalya F.
Format: Article
Language:English
Subjects:
Acoustic coupling
Acoustic propagation
Anisotropy
Attenuation
Broadband
Computer simulation
Coupling
Couplings
Crystal structure
Crystals
Devices
Leaky waves
LiNbO
Lithium niobates
longitudinal leaky surface acoustic wave (LLSAW)
Mathematical analysis
multilayered structure
Optimization
Piezoelectricity
Propagation velocity
Quartz
resonator
SAW device
Single crystals
Substrates
Surface acoustic wave devices
Surface acoustic waves
Thickness
Thin plates
Wave propagation
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Summary:Multilayered structures can successfully replace single crystal substrates in high-performance surface acoustic wave (SAW) devices. A combination of high propagation velocity and strong piezoelectric coupling is required for acoustic modes used in wideband high-frequency SAW devices. These characteristics can be achieved simultaneously in SAW devices arranged on a lithium niobate (LN) thin plate bonded to quartz and using longitudinal leaky SAW (LLSAW) if the orientations of both the crystals and the plate thickness are optimized. This article describes an optimization procedure developed to find low-attenuated LLSAWs in layered structures that can be used in LN/quartz applications. The symmetry consideration of two crystals was followed by the optimization of the LN orientation to achieve the largest electromechanical coupling and by an analysis of quartz anisotropy as a crucial factor of the existence of nonattenuated LLSAWs. Finally, the quartz orientation and LN thickness were optimized by a rigorous numerical simulation of resonator admittances and by the extraction of LLSAW attenuation at resonant and antiresonant frequencies. The discovered structures enable the propagation of LLSAWs with velocities in the range of 5400-6000 m/s, electromechanical coupling up to 18%, and negligible attenuation. High {Q} -factors can be achieved at resonance and antiresonance by the variation of the duty factor in the same layered structure. The specific behavior of the LLSAW attenuation with a variation of the LN thickness and quartz cut angle is illustrated by contour plots for each of the optimal structures discovered.
ISSN:0885-3010
1525-8955
DOI:10.1109/TUFFC.2020.2969298