Elastic wave propagation in nonlinear two-dimensional acoustic metamaterials

Zhao, Cheng; Zhang, Kai; Zhao, Pengcheng; Deng, Zichen

doi:10.1007/s11071-022-07259-z

Cited by 16 publications

(2 citation statements)

References 53 publications

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“…Inspired by the inertial amplification, more and more novel studies are proposed. For instance, an octahedron structure was built to isolate the special omnidirectional elastic waves [40]; incorporating inertial amplification structures in continuous beams to manipulate the transverse wave [41,42]; a 2D thin plates embedded the classical inertial amplifier structures was proposed to modulate lowfrequency and broad lamb waves [43,44]; the low-frequency vibration isolation of the corrugated-core 3 / 26 sandwich panels can be enhanced through embedding the inertial amplification system [45]; a levertype inertial amplification system can achieve the broadband isolation for the surface wave which is induced by the seismic [46,47]; the combination of the inertial amplification and local resonance can improve the extremely narrow effective attenuation of the classical local resonance bandgap [48] and release the dependence on lowering stiffness and increasing mass for low-frequency local resonance bandgap [49]； the multiple, broadband and highly attenuative bandgaps can be obtained by a system with inertial amplification, local resonance, and Bragg scattering affect simultaneously [50]. However, in the last two decades, the design strategies [42,45,[51][52][53][54][55] have been limited to the form of the classical inertial amplification sub-structure.…”

Section: Introductionmentioning

confidence: 99%

Isotacticity in chiral phononic crystals for low-frequency bandgap

Ding

Chen

et al. 2024

International Journal of Mechanical Sciences

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Section: Introductionmentioning

confidence: 99%

Isotacticity in chiral phononic crystals for low-frequency bandgap

Ding

Chen

et al. 2024

International Journal of Mechanical Sciences

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“…Acoustic metamaterials are artificial subwavelength structures with unconventional dynamic properties and remarkable functions, including local resonance metamaterials, [1][2][3][4][5][6][7][8][9] Helmholtz resonance metamaterials, [3] and membrane-type metamaterials [4,5] and other materials that can effectively achieve low-frequency attenuation, aroused the interest of a large number of researchers. Liu et al [10] used a high-density mass wrapped in a soft rubber material to form a local resonance unit using a simple cubic lattice form and Zhao et al [11] studied the dispersion relationship and wave propagation properties in nonlinear resonator two-dimensional acoustic metamaterials, and the results can be used to tune wave propagation in nonlinear acoustic metamaterials, providing some ideas for nonlinear research. The propagation of elastic waves in origami-inspired lattices was also studied, and it was found that origami-inspired lattices provided a new method for designing vibration-isolating structures.…”

Section: Introductionmentioning

confidence: 99%

Low Frequency Band Gap and Wave Propagation Properties of a Novel Fractal Hybrid Metamaterial

Cao

Yang

Ding

et al. 2022

Physica Status Solidi (b)

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In order to achieve the attenuation of low‐frequency sound, in this paper, a hybrid metamaterial structure with a complete band gap below 500 Hz is proposed, which is subjected to second‐order fractal, series fusion, and whether the structure is framed or not to form 8 different structures. Based on the finite element method and Bloch's theorem, the bandgap and transport properties of all model structures are evaluated, and the bandgap and propagation properties of metamaterial structures with different fractal levels are elucidated in terms of band structure and group velocity. In addition, the third‐order fractal structure and the dependence of the band gap on the material are also studied. The results show that the structure has a superior band gap width, and the complete band gap of its tandem fusion structure accounts for up to 45.502% in the range of 500 Hz, and the second‐order fractal has a complete band gap of 45.588% in the range of 1000 Hz. Compared with other structures, it can produce lower and better band gap. The research in this paper provides a new strategy for realizing acoustic metamaterial structures with low frequency band gaps.

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Elastic Wave Propagation in 2D Carbon Nano‐Onion Lattices

Lashani,

Ghavanloo

2024

Advcd Theory and Sims

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This study presents a simple analytical model to investigate wave propagation in 2D carbon nano‐onions (CNOs) and nitrogen‐doped carbon nano‐onions (N‐CNOs) lattices. Furthermore, the dispersion relationships of the waves and bandgaps in these lattices are derived based on Bloch's theorem. The CNOs and N‐CNOs lattices are modeled as infinite 2D mass‐in‐mass structures accurately assembled using linear springs. The Lennard–Jones potential energy is employed to obtain equivalent spring constants. A key finding of this research is the identification of bandgaps within all lattice structures, signifying regions where wave propagation is prohibited. The existence of these bandgaps offers potential for the advancement of adjustable nano‐scale metamaterials.

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Elastic wave propagation in nonlinear two-dimensional acoustic metamaterials

Cited by 16 publications

References 53 publications

Isotacticity in chiral phononic crystals for low-frequency bandgap

Isotacticity in chiral phononic crystals for low-frequency bandgap

Low Frequency Band Gap and Wave Propagation Properties of a Novel Fractal Hybrid Metamaterial

Elastic Wave Propagation in 2D Carbon Nano‐Onion Lattices

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