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In the present work, nonlinearities in temperature
compensating (TC) SAW devices are investigated. The materials
used are LiNbO3-rot128YX as the substrate and Copper electrodes covered with a SiO2-layer as the compensating layer.
In order to understand the role of these materials for the
nonlinearities in such acoustic devices, a FEM simulation model
in combination with a perturbation approach [1] is applied.
The nonlinear tensor data of the different materials involved
in TC-SAW devices have been taken from literature, but were
partially modified to fit experimental data by introducing scaling factors. An effective nonlinearity constant is determined
by comparison of nonlinear P-matrix simulations to IMD3
measurements of test filters. By employing these constants in
nonlinear periodic P-matrix simulations a direct comparison to
nonlinear periodic FEM-simulations yields the scaling factors for
the material used. Thus, the contribution of different materials
to the nonlinear behavior of TC-SAW devices is obtained and
the role of metal electrodes is discussed in detail
Elastic constants of components are usually determined by tensile tests in combination with ultrasonic
experiments. However, these properties may change due to e.g. mechanical treatments or service conditions during
their lifetime. Knowledge of the actual material parameters is key to the determination of quantities like residual
stresses present in the medium. In this work the acoustic nonlinearity parameter (ANP) for surface acoustic waves is
examined through the derivation of an evolution equation for the amplitude of the second harmonic. Given a certain
depth profile of the third-order elastic constants, the dependence of the ANP with respect to the input frequency is
determined and on the basis of these results, an appropriate inversion method is developed. This method is intended
for the extraction of the depth dependence of the third-order elastic constants of the material from second-harmonic
generation and guided wave mixing experiments, assuming that the change in the linear Rayleigh wave velocity is
small. The latter assumption is supported by a 3D-FEM model study of a medium with randomly distributed microcracks as well as theoretical works on this topic in the literature.