Giulia Aguzzi scite author profile

We amalgamate two fundamental designs from distinct areas of wave control in physics, and place them in the setting of elasticity. Graded elastic metasurfaces, so-called metawedges, are combined with the now classical Su-Schrieffer-Heeger (SSH) model from the field of topological insulators. The resulting structures form one-dimensional graded-SSH metawedges that support multiple, simultaneous, topologically protected edge states. These robust, enhanced localized modes are leveraged for applications in elastic energy harvesting using the piezoelectric effect. The designs we develop are first motivated by applying the SSH model to mass-loaded Kirchhoff-Love thin elastic plates. We then extend these ideas to using graded resonant rods, and create SSH models, coupled to elastic beams and full elastic half-spaces.

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Mitigation of seismic waves: Metabarriers and metafoundations bench tested

Colombi

Zaccherini

Aguzzi

et al. 2020

Journal of Sound and Vibration

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Nonlinear periodic foundations for seismic protection: Practical design, realistic evaluation and stability considerations

Martakis

Aguzzi

Dertimanis

et al. 2021

Soil Dynamics and Earthquake Engineering

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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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Numerical Investigation of Structured Materials for Vibration Control

Aguzzi¹,

Colombi²,

Chatzi³

2020

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Giulia Aguzzi

Topological Rainbow Trapping for Elastic Energy Harvesting in Graded Su-Schrieffer-Heeger Systems

Mitigation of seismic waves: Metabarriers and metafoundations bench tested

Nonlinear periodic foundations for seismic protection: Practical design, realistic evaluation and stability considerations

Octet lattice-based plate for elastic wave control

Numerical Investigation of Structured Materials for Vibration Control

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