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Low frequency band gap and vibration suppression mechanism of innovative multiphase metamaterials

Bin Wang, Hong-yun Yang, Ya‐jun Xin, Yongtao Sun, Shu-liang Cheng, Liang Wang, Shuo Wang, Zhao-zhan Zhang

2023Mechanics of Advanced Materials and Structures15 citationsDOI

Abstract

In order to achieve low frequency vibration and noise reduction, researchers have found and explored many types of metamaterial structures. Based on this, an innovative multiphase metamaterial structure composed of hard materials and soft materials is proposed in this paper. According to Bloch’s theorem, the band gap characteristics of the proposed structure are calculated using the finite element method, and the formation mechanism of the band gap is analyzed. In addition, the effects of the stiffness and density of the two materials on the band gap are studied in detail. Then, the phase velocity, group velocity and wave propagation direction are calculated according to a certain frequency of the specific dispersion curve, and the important information of wave propagation in the structure is obtained. Finally, according to the transmission characteristics of vibration in a finite periodic structure, it is verified that the existence of band gap can inhibit the vibration transmission, and it is further clarified that the proposed structure has a good performance in the design of low-frequency band gaps with large amplitude.

Topics & Concepts

MetamaterialVibrationBand gapFrequency bandFinite element methodAcousticsTransmission (telecommunications)Materials scienceGroup velocityBloch waveStiffnessDispersion (optics)Noise (video)Wave propagationAcoustic metamaterialsPhysicsStructural engineeringOpticsCondensed matter physicsEngineeringOptoelectronicsComputer scienceTelecommunicationsBandwidth (computing)Composite materialArtificial intelligenceImage (mathematics)Acoustic Wave Phenomena ResearchNoise Effects and ManagementMetamaterials and Metasurfaces Applications
Low frequency band gap and vibration suppression mechanism of innovative multiphase metamaterials | Litcius