Deformation behavior and band gap switching function of 4D printed multi-stable metamaterials

• Published in: Materials & design Vol. 200; p. 109481
• Main Authors: Hu, Wenxia, Ren, Zhiwen, Wan, Zhishuai, Qi, Dexing, Cao, Xiaofei, Li, Zhen, Wu, Wenwang, Tao, Ran, Li, Ying
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 15.02.2021; Elsevier
• Subjects: 3D printed; Bandgap; Metamaterial; Multi-stable; Shape memory polymer; Multi-stable; Metamaterial; Shape memory polymer; 3D printed; Bandgap
• ISSN: 0264-1275; 1873-4197
• DOI: 10.1016/j.matdes.2021.109481

Metamaterials/Phononic crystals are used to control the propagation of elastic waves/sound waves, and can be used in fields such as vibration isolation, noise reduction, stealth, focusing, and acoustic wave devices. The realization of real-time, flexible and active adjustable control of elastic waves by mechanical reconstruction of metamaterials is a current research hotspot. Here, SMP metamaterials with mechanical reconstruction and self-recovery ability are proposed. Affected by the glass transition temperature of the material, the mechanical properties of the metamaterials are related to the geometric parameters of the lattice configuration and the external temperature. The metamaterials can adaptively switch mechanical properties and shapes without continuous external excitation of the physical field. The finite element method and experiments were used to analyze the deformation and self-recovery process of the metamaterials. The results show that the metamaterial can achieve mechanical programming and response recovery, and the bandgap of the metamaterial can be greatly adjusted by changing the external temperature. [Display omitted] •The Shape memory polymer (SMP) metamaterials with mechanical reconstruction and self-recovery ability are proposed.•FEA and experiments were used to analyze the deformation and self-recovery process of the metamaterials.•The metamaterial can achieve mechanical programming, response recovery and adjust the band gap.