SAW propagation loss mechanism in piezoelectric ceramics

Abstract

The surface acoustic wave (SAW) propagation loss mechanism of piezoelectric ceramics is examined using lead titanate (PbTiO₃) ceramics modified with additives of Nd₂O₃, MnO₂, and In₂O₃, which have zero temperature coefficients of SAW delay time. The propagation loss L in the frequency range 30 to 300 MHz consists of two parts. One is the Rayleigh scattering loss L_S caused by grain, and the other is the true dissipative loss L_F caused by internal friction. Thus, total loss results in L(dB/cm) = L_S+L_F = 3.2×10³D³f⁴+6.8×10⁻⁴f² (where D and f denote average grain size in cm and frequency in MHz, respectively). It is also revealed experimentally that the internal friction causing the latter loss has a close correlation with the dielectric loss through piezoelectric combination. Therefore, materials with fine grain (−3) must be developed to reduce SAW propagation losses which prevent the piezoelectric ceramics from being used in higher frequency (≳100 MHz) SAW applications. Based on these requirements, fine grained (∼0.5 μm) specimens are fabricated. The propagation losses obtained from these specimens, 9 dB/cm at 100 MHz, are the lowest values ever reported for piezoelectric ceramics. This result suggests that the present ceramics have high potential as materials for high‐frequency SAW devices.