Excitation of fundamental shear horizontal wave by using face-shear (d36) piezoelectric ceramics

TL;DR

This paper demonstrates the effective excitation of non-dispersive shear horizontal (SH0) waves in plates using specially engineered face-shear (d36) mode piezoelectric ceramics, advancing non-destructive testing and structural health monitoring techniques.

Contribution

The study develops enhanced face-shear PZT ceramics through lateral compression and temperature treatment, enabling efficient SH0 wave excitation in aluminum plates, which was previously limited by conventional ceramics.

Findings

Face-shear PZT-4 exhibits superior performance over PZT-5H.

SH0 wave is dominant between 160 kHz and 280 kHz.

Wave amplitude remains high within 30° deviation from main directions.

Abstract

The fundamental shear horizontal (SH0) wave in plate-like structures is extremely useful for non-destructive testing (NDT) and structural health monitoring (SHM) as it is non-dispersive. However, currently the SH0 wave is usually excited by electromagnetic acoustic transducers (EMAT) whose energy conversion efficiency is fairly low. The face-shear (d36) mode piezoelectrics is more promising for SH0 wave excitation but this mode cannot appear in conventional piezoelectric ceramics. Recently, by modifying the symmetry of poled PbZr1-xTixO3 (PZT) ceramics via ferroelastic domain engineering, we realized the face-shear d36 mode in both soft and hard PZT ceramics. In this work, we further improved the face-shear properties of PZT-4 and PZT-5H ceramics via lateral compression under elevated temperature. It was found that when bonded on a 1 mm-thick aluminum plate, the d36 type PZT-4 exhibited better face-shear performance than PZT-5H. We then successfully excite SH0 wave in the aluminum plate using a face-shear PZT-4 square patch and receive the wave using a face-shear PMN-PT patch. The frequency response and directionality of the excited SH0 wave were also investigated. The SH0 wave can be dominate over the Lamb waves (S0 and A0 waves) from 160 kHz to 280 kHz. The wave amplitude reaches its maxima along the two main directions (0{\deg} and 90{\deg}). The amplitude can keep over 80% of the maxima when the deviate angle is less than 30{\deg}, while it vanishes quickly at the 45{\deg} direction. The excited SH0 wave using piezoelectric ceramics could be very promising in the fields of NDT and SHM.