Multifunctional 3D lattice metamaterials for vibration mitigation and energy absorption

Complex engineering applications have created an increasing demand for engineering structures or materials with multiple desired properties. In this context, metamaterials endowed with multifunctionalities through their structural configuration show unique advantages over traditional materials. Here, we present a novel three-dimensional lattice structure with simultaneous vibration mitigation and energy absorption capabilities. The results of numerical simulations and experimental tests demonstrate that the proposed metastructure is capable of attenuating low-frequency elastic waves through local resonance and absorbing impact energy through buckling deformation. Importantly, the local resonance is achieved by introducing the lightweight struts rather than additional heavy masses. Moreover, a functionally graded strategy is implemented to further enhance the vibration mitigation and energy absorption performance of the lattice metamaterial. The findings obtained in this study suggest a promising pathway for the development of multifunctional metamaterials for various specific applications.

Automated summary

Complex engineering applications have created a demand for engineering structures or materials with multiple desired properties. This study presents a novel three-dimensional lattice structure with simultaneous vibration mitigation and energy absorption capabilities. Results show that the proposed metastructure can attenuate low-frequency elastic waves through local resonance and absorb impact energy through buckling deformation. The study also implements a functionally graded strategy to enhance the performance of the lattice metamaterial.