Measurement of the electric permittivity using Bleustein-Gulyaev wave sensor

We present a novel compact electric permittivity sensor that exploits Bleustein-Gulyaev waves propagating along the surface of shear-poled piezoelectrics. We formulate the dynamic nonlinear electromechanical partial differential equations of motion governing wave propagation under electromagnetically quasistatic conditions. The permittivity of the medium-under-test was found to influence the sensor eigenvalues, enabling the implementation of a frequency-shift permittivity sensor. Solution of the equations of motion demonstrates resonance of the first and third modes when excited using an interdigitated transducer. We fabricated two sensor prototypes on shear-poled PZT4 and LiNbO3 substrates and used a Vector Network Analyzer to observe the shift in their fundamental natural frequency in the presence of various media-under-test. S-11 measurements show deterministic and repeatable shifts in the resonant frequency of the first mode of the LiNbO3 sensor measured at Delta f(1) = 3.51 MHz for ethanol and Delta f(1 )= 7.49 MHz for deionized water where the bare surface frequency was initially at f(1) = 25.27 MHz.

Automated summary

This paper presents a novel compact electric permittivity sensor that utilizes Bleustein-Gulyaev waves propagating along the surface of shear-poled piezoelectrics. The sensor eigenvalues are influenced by the permittivity of the medium-under-test, enabling the implementation of a frequency-shift permittivity sensor. Experimental results demonstrate resonance of the first and third modes when excited using an interdigitated transducer. Sensor prototypes fabricated on shear-poled PZT4 and LiNbO3 substrates show a shift in their fundamental natural frequency in the presence of different media-under-test.