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Broadening low-frequency bandgaps in locally resonant piezoelectric metamaterials by negative capacitance

•Negative capacitance enlarges bandgaps in resonant piezoelectric metamaterials.•The enlargement of bandgap is not simply because the coupling factor is enhanced.•Influences of negative capacitance strongly depends on the covering ratio of patches.•The effective medium theory cannot well predict ban...

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Bibliographic Details
Published in:Journal of sound and vibration 2021-02, Vol.493, p.115837, Article 115837
Main Authors: Yi, Kaijun, Collet, Manuel
Format: Article
Language:English
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Summary:•Negative capacitance enlarges bandgaps in resonant piezoelectric metamaterials.•The enlargement of bandgap is not simply because the coupling factor is enhanced.•Influences of negative capacitance strongly depends on the covering ratio of patches.•The effective medium theory cannot well predict bandgaps in piezoelectric metamaterials. This paper combines negative capacitance (NC) with inductance (L) to enlarge low-frequency bandgap width in locally resonant piezoelectric metamaterials. The studied metamaterials are obtained by directly bonding patches on the surfaces of host structures, then connecting patches to shunts. Shunts with NC and L in series and in parallel are both studied. Analytical expressions of the bandgap ranges are derived, which reveal that the bandgap size is increased not simply because the NC enhancing the material’s electro-mechanical coupling factor, but in a more complicated way. Parametric studies are performed to analytically investigate the tuning properties of the LR bandgap by NC. Results demonstrate that by modifying NC value, the LR bandgap size can be significantly increased. Numerical simulations are done to verify the effects of the broadened bandgap on vibration transmission and reveal the limitations of the used analytical model. Practical implementation of the shunts are also discussed, recommendations on choosing the shunt configurations and NC values are given. This paper gives a theoretical guideline on designing piezoelectric metamaterials with bandgap effects at desired frequency ranges for practical applications like low-frequency vibration and noise reduction or isolation.
ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2020.115837