Litcius/Paper detail

Adaptive control on flexural waves by a piezoelectric-based elastic metasurface with hybrid shunting circuits

Zoe Yaw, Weijian Zhou, C.W. Lim

2023Mechanics of Advanced Materials and Structures22 citationsDOI

Abstract

In aspects of its simple configuration and tunability, piezoelectric-based metasurface has benefited over its mechanical counterpart in adaptive wavefront manipulation. By tuning the circuitry elements in the shunting circuits properly, the equivalent material properties of the metasurface can be modified to attain a complete 2π phase shift and to maintain high transmission at desired working frequencies. In this paper, a piezoelectric-based elastic metasurface with hybrid shunting circuits (NC–LC–NC shunts) are proposed to adaptively control the propagation of flexural waves. Through tuning of negative capacitance and inductance simultaneously, the proposed elastic metasurface can cover a phase shift ranging from 0−2π while having a high transmission (≥0.7). It is discovered that any similar metasurface structural design with solely single shunting circuit presently available could not achieve the same results as the proposed elastic metasurface. In addition, analytical modeling based on equivalent Young’s modulus is developed and a finite element model is built to study the transmission and phase shift of the proposed metasurface. It is demonstrated numerically that the proposed piezoelectric-based elastic metasurface is capable of performing switchable functionalities, such as wave refraction and focusing, at different working frequencies (3500 Hz, 5000 Hz, etc.).

Topics & Concepts

Electronic circuitPiezoelectricityAcousticsShuntingTransmission (telecommunications)Materials scienceFlexural strengthPhase (matter)WavefrontOpticsInductanceElectronic engineeringPhysicsEngineeringElectrical engineeringVoltageInternal medicineQuantum mechanicsComposite materialMedicineAcoustic Wave Phenomena ResearchVibration Control and Rheological FluidsMetamaterials and Metasurfaces Applications