Locally Resonant Metasurfaces for Shear Waves in Granular Media

Zaccherini, Rachele; Colombi, Andrea; Palermo, Antonio; Dertimanis, Vasilis K.; Marzani, Alessandro; Thomsen, Henrik R.; Stojadinović, Božidar; Chatzi, Eleni

doi:10.1103/physrevapplied.13.034055

Cited by 38 publications

(18 citation statements)

References 45 publications

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“…4 d. Furthermore, by comparing this spectrum with the displacement field in a receiver on the edge of the metastructure ( ), black line in Fig. 4 d, we observe that the majority of the energy with frequency content within the forbidden range is converted into reflections 63 . The wavefront impacting on the metabarrier at 7.2 ms, propagates backward in the plate at t =8.8 ms (Fig.…”

Section: Resultsmentioning

confidence: 87%

“…At t =7.2 ms, the flexural waves scattered by the resonating mass-struts in the metawedge interfere destructively with the unscattered incoming field, impeding the transmission of energy 62 . The resulting energy gap, originated by the hybridization between the asymmetric propagating Lamb wave and the coalescence of the resonant bending mode of the struts and Bragg scattering, induces splitting of the incident wavefront 63 , as depicted in Fig. 4 a, c.…”

Section: Resultsmentioning

confidence: 99%

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Octet lattice-based plate for elastic wave control

Aguzzi

Kanellopoulos

Wiltshaw

et al. 2022

Sci Rep

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Motivated by the importance of lattice structures in multiple fields, we numerically investigate the propagation of flexural waves in a thin reticulated plate augmented with two classes of metastructures for wave mitigation and guiding, namely metabarriers and metalenses. The cellular architecture of this plate invokes the well-known octet topology, while the metadevices rely on novel customized octets either comprising spherical masses added to the midpoint of their struts or variable node thickness. We numerically determine the dispersion curves of a doubly-periodic array of octets, which produce a broad bandgap whose underlying physics is elucidated and leveraged as a design paradigm, allowing the construction of a metabarrier effective for inhibiting the transmission of waves. More sophisticated effects emerge upon parametric analyses of the added masses and node thickness, leading to graded designs that spatially filter waves through an enlarged bandgap via rainbow trapping. Additionally, Luneburg and Maxwell metalenses are realized using the spatial modulation of the tuning parameters and numerically tested. Wavefronts impinging on these structures are progressively curved within the inhomogeneous media and steered toward a focal point. Our results yield new perspectives for the use of octet-like lattices, paving the way for promising applications in vibration isolation and energy focusing.

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Section: Resultsmentioning

confidence: 87%

Section: Resultsmentioning

confidence: 99%

Octet lattice-based plate for elastic wave control

Aguzzi

Kanellopoulos

Wiltshaw

et al. 2022

Sci Rep

Self Cite

View full text Add to dashboard Cite

show abstract

“…(3) Topography and seismic metamaterials. Seismic metamaterials could be built to deflect or dissipate seismic waves before they arrive at the test mass, potentially suppressing surface wave amplitudes by a factor of a few [67][68][69][70][71][72]. Similarly, berms, ditches, and other nearby topographic features can affect the propagation of seismic waves and thus the Newtonian noise level.…”

Section: Mitigation Strategiesmentioning

confidence: 99%

Gravitational-wave physics with Cosmic Explorer: Limits to low-frequency sensitivity

et al. 2021

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Cosmic Explorer is a next-generation ground-based gravitational-wave observatory concept, envisioned to begin operation in the 2030s and expected to be capable of observing binary neutron star and black hole mergers back to the time of the first stars. Cosmic Explorer's sensitive band will extend below 10 Hz, where the design is predominantly limited by geophysical, thermal, and quantum noises. In this work, thermal, seismic, gravity-gradient, quantum, residual gas, scattered-light, and servo-control noises are analyzed in order to motivate facility and vacuum system design requirements, potential test mass suspensions, Newtonian noise reduction strategies, improved inertial sensors, and cryogenic control requirements. Our analysis shows that, with improved technologies, Cosmic Explorer can deliver a strain sensitivity better than 10 −23 Hz −1=2 down to 5 Hz. Our work refines and extends previous analysis of the Cosmic Explorer concept and outlines the key research areas needed to make this observatory a reality.

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“…energy harvesting [17], and sound and vibration isolation [18,19,20]. Bandgaps are commonly generated via two different mechanisms, namely, Bragg scattering [21,22] and local resonances [23,24].…”

Section: Introductionmentioning

confidence: 99%

Stress-optimized inertial amplified metastructure with opposite chirality for vibration attenuation

Zaccherini¹,

Colombi²,

Palermo³

et al. 2021

Preprint

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In this work, we investigate the dynamics and attenuation properties of a one-dimensional inertial amplified lattice with opposite chirality. The unit cell of the structure consists of a hollow-square plate connected to a ring through arch-like ligaments. The peculiar geometry and orientation of the links allow for coupling the axial and the torsional motion of the lattice, thus amplifying the inertia of the system. We develop both simplified analytical and numerical models of the building block to derive the complex dispersion relation of the infinite lattice. The structure supports a frequency-tailorable attenuation zone, whose lower bound is controlled by the second coupled axial-torsional mode. Laboratory measurements of the transmission spectrum on a 3D printed sample match very well with the analytical and numerical predictions, confirming the wide-band filtering properties of this lattice. We complete our investigation by developing and solving a constrained optimization model to obtain the optimized geometric parameters of the unit cell that minimize the bandgap opening frequency and, at the same time, fulfill structural requirements. In particular, the internal stresses induced by the self-weight of the structure are kept to a low by virtue of the employed design, with the aim to prevent plastic deformations and failure. The inertial amplification mechanism, proposed and investigated in this work, offers an efficient variant for the efficient design of materials and structures for vibration mitigation and shock protection.

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Locally Resonant Metasurfaces for Shear Waves in Granular Media

Cited by 38 publications

References 45 publications

Octet lattice-based plate for elastic wave control

Octet lattice-based plate for elastic wave control

Gravitational-wave physics with Cosmic Explorer: Limits to low-frequency sensitivity

Stress-optimized inertial amplified metastructure with opposite chirality for vibration attenuation

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