Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam
Attenuation of elastic waves in the extremely low frequency range is a considerable challenge. While linear acoustic metamaterials can manipulate elastic waves, their effectiveness is often limited to a narrow frequency range. The present paper proposes a novel inertant nonlinear metamaterial beam t...
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sg-ntu-dr.10356-1824762025-02-04T04:11:08Z Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam Lou, Jia Zhang, Songliang Fan, Hui Fang, Xiang Du, Jianke School of Mechanical and Aerospace Engineering Engineering Nonlinear metamaterials Ultra-low frequency band gaps Attenuation of elastic waves in the extremely low frequency range is a considerable challenge. While linear acoustic metamaterials can manipulate elastic waves, their effectiveness is often limited to a narrow frequency range. The present paper proposes a novel inertant nonlinear metamaterial beam to address the challenging problem of the ultra-low frequency broadband flexural wave attenuation. The amplitude-frequency response and dispersion relations of the flexural waves are obtained using the first-order harmonic balance method, where four different resonant units are investigated and the resulting band gaps are compared. Finite element (FE) simulations are also conducted to evaluate the transmission spectra of the flexural vibration through a finite metamaterial beam. The good consistency between the band gaps predicted by the analytical model and the FE simulation verifies the correctness and effectiveness of the developed analytical approach. The results of this study demonstrate that introducing the inertance and softening nonlinearity into the resonant units can significantly widen the flexural wave band gaps within the low-frequency range. This finding provides a viable solution for engineering applications that require low-frequency vibration suppression and isolation. Ministry of Education (MOE) The present work was funded by the China Scholarship Council (No. 202208330229), Singapore MOE AcRF Tier 1 (No. RG145/23), the Key Program of the Natural Science Foundation of Zhejiang Province (No. LZ22A020001), and the Ningbo Major Research and Development Plan Project (No. 2022Z210). 2025-02-04T04:11:08Z 2025-02-04T04:11:08Z 2025 Journal Article Lou, J., Zhang, S., Fan, H., Fang, X. & Du, J. (2025). Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam. Engineering Structures, 323, 119169-. https://dx.doi.org/10.1016/j.engstruct.2024.119169 0141-0296 https://hdl.handle.net/10356/182476 10.1016/j.engstruct.2024.119169 2-s2.0-85207801105 323 119169 en RG145/23 Engineering Structures © 2024 Elsevier Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. |
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Engineering Nonlinear metamaterials Ultra-low frequency band gaps |
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Engineering Nonlinear metamaterials Ultra-low frequency band gaps Lou, Jia Zhang, Songliang Fan, Hui Fang, Xiang Du, Jianke Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| description |
Attenuation of elastic waves in the extremely low frequency range is a considerable challenge. While linear acoustic metamaterials can manipulate elastic waves, their effectiveness is often limited to a narrow frequency range. The present paper proposes a novel inertant nonlinear metamaterial beam to address the challenging problem of the ultra-low frequency broadband flexural wave attenuation. The amplitude-frequency response and dispersion relations of the flexural waves are obtained using the first-order harmonic balance method, where four different resonant units are investigated and the resulting band gaps are compared. Finite element (FE) simulations are also conducted to evaluate the transmission spectra of the flexural vibration through a finite metamaterial beam. The good consistency between the band gaps predicted by the analytical model and the FE simulation verifies the correctness and effectiveness of the developed analytical approach. The results of this study demonstrate that introducing the inertance and softening nonlinearity into the resonant units can significantly widen the flexural wave band gaps within the low-frequency range. This finding provides a viable solution for engineering applications that require low-frequency vibration suppression and isolation. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Lou, Jia Zhang, Songliang Fan, Hui Fang, Xiang Du, Jianke |
| format |
Article |
| author |
Lou, Jia Zhang, Songliang Fan, Hui Fang, Xiang Du, Jianke |
| author_sort |
Lou, Jia |
| title |
Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| title_short |
Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| title_full |
Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| title_fullStr |
Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| title_full_unstemmed |
Ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| title_sort |
ultra-low frequency and broadband flexural wave attenuation using an inertant nonlinear metamaterial beam |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182476 |
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1823807362834628608 |