Spider web-inspired acoustic metamaterials

Miniaci, Marco; Krushynska, Anastasiia O.; Movchan, A. B.; Bosia, Federico; Pugno, Nicola

doi:10.1063/1.4961307

Cited by 91 publications

(50 citation statements)

References 30 publications

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“…This study represents the first step towards the investigation of large amplitude waves in beam lattices in 2D and 3D. While periodic lattices have recently attracted considerable interest because of their ability to tailor the propagation of linear elastic waves through directional transmissions and band gaps (frequency ranges of strong wave attenuation) [39][40][41][42][43], comparatively little is known about their nonlinear behaviors under high-amplitude impacts [20]. The results presented in this paper provide useful guidelines for future explorations of the propagation of nonlinear waves in lattice materials.…”

Section: Discussionmentioning

confidence: 99%

Propagation of elastic solitons in chains of pre-deformed beams

Deng

Zhang

et al. 2019

New J. Phys.

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We use a combination of experiments, numerical analysis and theory to investigate the nonlinear dynamic response of a chain of precompressed elastic beams. Our results show that this simple system offers a rich platform to study the propagation of large amplitude waves. Compression waves are strongly dispersive, whereas rarefaction pulses propagate in the form of solitons. Further, we find that the model describing our structure closely resembles those introduced to characterize the dynamics of several molecular chains and macromolecular crystals, suggesting that our macroscopic system can provide insights into the effect of nonlinear vibrations on molecular mechanisms.

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Section: Discussionmentioning

confidence: 99%

Propagation of elastic solitons in chains of pre-deformed beams

Deng

Zhang

et al. 2019

New J. Phys.

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“…Our study introduces a theoretical biologically inspired mechanism that automatically resets each element to a high potential energy state, allowing the transmission of further signals. Many recent studies introduce the idea of manipulating biological subsystems in materials [22][23][24], or discuss behaviours that arise in active matter systems, where biological systems exert mechanical forces [25]. Some systems are biologically inspired [21,23,24] where properties of the metamaterial are designed to mimic a biological phenomenon, and some systems exploit the properties of biological subsystems to produce new behaviours in the material [22].…”

Section: Introductionmentioning

confidence: 99%

Reversible signal transmission in an active mechanical metamaterial

2019

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Mechanical metamaterials are designed to enable unique functionalities, but are typically limited by an initial energy state and require an independent energy input to function repeatedly. Our study introduces a theoretical active mechanical metamaterial that incorporates a biological reaction mechanism to overcome this key limitation of passive metamaterials. Our material allows for reversible mechanical signal transmission, where energy is reintroduced by the biologically motivated reaction mechanism. By analysing a coarse grained continuous analogue of the discrete model, we find that signals can be propagated through the material by a travelling wave. Analysis of the continuum model provides the region of the parameter space that allows signal transmission, and reveals similarities with the well-known FitzHugh-Nagumo system. We also find explicit formulae that approximate the effect of the timescale of the reaction mechanism on the signal transmission speed, which is essential for controlling the material.

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“…In this case, low-frequency band gaps may be obtained, even if heavy resonators and low stiffness cells are required to get wide stop-bands. Improvements in creating wide low frequency band gaps have been obtained by virtue of the concept of effective inertia, consisting in amplifying a small mass through embedded amplification mechanisms (see Yilmaz et al, 2007, Acar and Yilmaz, 2013, Taniker and Yilmaz, 2015, Frandsen et al, 2016 or by mimicking biological structural systems (see Miniaci et al, 2016 andMiniaci et al, 2018). Recently, Yin et al, 2014, and Chen and Wang, 2015, obtained ultra-wide lowfrequency band gaps in composites designed on the thought of staggered and combined soft and hard materials.…”

Section: Introductionmentioning

confidence: 99%

Acoustic waveguide filters made up of rigid stacked materials with elastic joints

et al. 2019

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The acoustic dispersion properties of monodimensional waveguide filters can be assessed by means of the simple prototypical mechanical system made of an infinite stack of periodic massive blocks, connected to each other by elastic joints. The linear undamped dynamics of the periodic cell is governed by a two degree-of-freedom Lagrangian model. The eigenproblem governing the free propagation of shear and moment waves is solved analytically and the two dispersion relations are obtained in a suited closed form fashion.Therefore, the pass and stop bandwidths are conveniently determined in the minimal space of the independent mechanical parameters. Stop bands in the ultra-low frequency range are achieved by coupling the stacked material with an elastic half-space modelled as a Winkler support. A convenient fine approximation of the dispersion relations is pursued by formulating homogenised micropolar continuum models. An enhanced continualization approach, employing a proper Maclaurin approximation of pseudo-differential operators, is adopted to successfully approximate the acoustic and optical branches of the dispersion spectrum of the Lagrangian models, both in the absence and in the presence of the elastic support.

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Spider web-inspired acoustic metamaterials

Cited by 91 publications

References 30 publications

Propagation of elastic solitons in chains of pre-deformed beams

Propagation of elastic solitons in chains of pre-deformed beams

Reversible signal transmission in an active mechanical metamaterial

Acoustic waveguide filters made up of rigid stacked materials with elastic joints

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