Space-time wave localization in electromechanical metamaterial beams with programmable defects

TL;DR

This paper demonstrates a method for dynamically controlling wave localization in electromechanical metamaterials by moving programmable defects, enabling precise energy transfer and localization in complex structures.

Contribution

It introduces a novel strategy for programmable wave localization in electromechanical metamaterials using spatial-temporal defect modulation, applicable to complex 2D systems.

Findings

Effective wave localization achieved through defect movement

Demonstrated control in 2D piezoelectric lattice

Potential applications in sensing and energy harvesting

Abstract

A flexible wave localization is investigated using a spatial-temporal modulation of point defects along the periodic array of electromechanical local resonators of a piezoelectric bimorph beam. By changing the electrical resonance of subsequent unit cells through a smooth and synchronized strategy, a point defect is moved along the metastructure, which properly transfers the vibration energy between the unit cells as well as perfectly induces wave localization according to the final defect position. This wave manipulation by programmable defects is also applied to a two-dimensional triangular lattice composed by piezoelectric metamaterial beams, which illustrates the potential and versatility of the proposed strategy in more complex systems. Therefore, this work opens new possibilities for programmable wave localization and manipulation using smart electromechanical metamaterials with applications that may involve guiding, sensing, monitoring and harvesting.