Spider web-inspired acoustic metamaterials

Marco Miniaci; Anastasiia Krushynska; Alexander B. Movchan; Federico Bosia; Nicola M. Pugno

doi:10.1063/1.4961307

Spider web-inspired acoustic metamaterials

Marco Miniaci, Anastasiia Krushynska, Alexander B. Movchan, Federico Bosia, Nicola M. Pugno

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Spider silk is a remarkable example of bio-material with superior mechanical characteristics. Its multilevel structural organization of dragline and viscid silk leads to unusual and tunable properties, extensively studied from a quasi-static point of view. In this study, inspired by the Nephila spider orb web architecture, we propose a design for mechanical metamaterials based on its periodic repetition. We demonstrate that spider-web metamaterial structure plays an important role in the dynamic response and wave attenuation mechanisms. The capability of the resulting structure to inhibit elastic wave propagation in sub-wavelength frequency ranges is assessed, and parametric studies are performed to derive optimal configurations and constituent mechanical properties. The results show promise for the design of innovative lightweight structures for tunable vibration damping and impact protection, or the protection of large scale infrastructure such as suspended bridges. Published by AIP Publishing.

Original language	English
Article number	071905
Number of pages	4
Journal	Applied Physics Letters
Volume	109
Issue number	7
DOIs	https://doi.org/10.1063/1.4961307
Publication status	Published - 15-Aug-2016
Externally published	Yes

Keywords

BAND-GAPS
DESIGN
NANOSCALE
SOUND
SILKS

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title = "Spider web-inspired acoustic metamaterials",

abstract = "Spider silk is a remarkable example of bio-material with superior mechanical characteristics. Its multilevel structural organization of dragline and viscid silk leads to unusual and tunable properties, extensively studied from a quasi-static point of view. In this study, inspired by the Nephila spider orb web architecture, we propose a design for mechanical metamaterials based on its periodic repetition. We demonstrate that spider-web metamaterial structure plays an important role in the dynamic response and wave attenuation mechanisms. The capability of the resulting structure to inhibit elastic wave propagation in sub-wavelength frequency ranges is assessed, and parametric studies are performed to derive optimal configurations and constituent mechanical properties. The results show promise for the design of innovative lightweight structures for tunable vibration damping and impact protection, or the protection of large scale infrastructure such as suspended bridges. Published by AIP Publishing.",

keywords = "BAND-GAPS, DESIGN, NANOSCALE, SOUND, SILKS",

author = "Marco Miniaci and Anastasiia Krushynska and Movchan, {Alexander B.} and Federico Bosia and Pugno, {Nicola M.}",

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AU - Miniaci, Marco

AU - Krushynska, Anastasiia

AU - Movchan, Alexander B.

AU - Bosia, Federico

AU - Pugno, Nicola M.

PY - 2016/8/15

Y1 - 2016/8/15

N2 - Spider silk is a remarkable example of bio-material with superior mechanical characteristics. Its multilevel structural organization of dragline and viscid silk leads to unusual and tunable properties, extensively studied from a quasi-static point of view. In this study, inspired by the Nephila spider orb web architecture, we propose a design for mechanical metamaterials based on its periodic repetition. We demonstrate that spider-web metamaterial structure plays an important role in the dynamic response and wave attenuation mechanisms. The capability of the resulting structure to inhibit elastic wave propagation in sub-wavelength frequency ranges is assessed, and parametric studies are performed to derive optimal configurations and constituent mechanical properties. The results show promise for the design of innovative lightweight structures for tunable vibration damping and impact protection, or the protection of large scale infrastructure such as suspended bridges. Published by AIP Publishing.

AB - Spider silk is a remarkable example of bio-material with superior mechanical characteristics. Its multilevel structural organization of dragline and viscid silk leads to unusual and tunable properties, extensively studied from a quasi-static point of view. In this study, inspired by the Nephila spider orb web architecture, we propose a design for mechanical metamaterials based on its periodic repetition. We demonstrate that spider-web metamaterial structure plays an important role in the dynamic response and wave attenuation mechanisms. The capability of the resulting structure to inhibit elastic wave propagation in sub-wavelength frequency ranges is assessed, and parametric studies are performed to derive optimal configurations and constituent mechanical properties. The results show promise for the design of innovative lightweight structures for tunable vibration damping and impact protection, or the protection of large scale infrastructure such as suspended bridges. Published by AIP Publishing.

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Spider web-inspired acoustic metamaterials

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Keywords

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