M
Marco Miniaci
Researcher at university of lille
Publications - 66
Citations - 2180
Marco Miniaci is an academic researcher from university of lille. The author has contributed to research in topics: Metamaterial & Band gap. The author has an hindex of 20, co-authored 61 publications receiving 1461 citations. Previous affiliations of Marco Miniaci include University of Turin & Georgia Institute of Technology.
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Journal ArticleDOI
Large scale mechanical metamaterials as seismic shields
Marco Miniaci,Anastasiia Krushynska,Federico Bosia,Nicola M. Pugno,Nicola M. Pugno,Nicola M. Pugno +5 more
TL;DR: In this article, the feasibility of a passive isolation strategy for seismic waves based on large-scale mechanical metamaterials is discussed, including numerical analysis of both surface and guided seismic waves, soil dissipation effects, and adopting a full 3D simulations.
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Observation of topologically protected helical edge modes in Kagome elastic plates
TL;DR: In this article, an elastic plate patterned according to a Kagome architecture with an accidental degeneracy of two Dirac cones induced by drilling through holes is proposed to obtain topologically protected helical edge waves in elastic media.
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Experimental Observation of Topologically Protected Helical Edge Modes in Patterned Elastic Plates
TL;DR: In this article, the first experimental demonstration of topologically protected helical edge modes, a robust approach to manipulating vibrations, with potential applications in sensing-signal processing and wave guiding.
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Coupling local resonance with Bragg band gaps in single-phase mechanical metamaterials
Anastasiia Krushynska,Marco Miniaci,Federico Bosia,Nicola M. Pugno,Nicola M. Pugno,Nicola M. Pugno +5 more
TL;DR: In this paper, the authors theoretically analyze a single-phase solid metamaterial with quasi-resonant Bragg band gaps and show evidence that the latter are achieved by obtaining an overlap of the Bragg gap with local resonance modes of the matrix material, instead of the inclusion.
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Proof of Concept for an Ultrasensitive Technique to Detect and Localize Sources of Elastic Nonlinearity Using Phononic Crystals.
Marco Miniaci,Antonio Gliozzi,Bruno Morvan,Anastasiia Krushynska,Federico Bosia,Marco Scalerandi,Nicola M. Pugno,Nicola M. Pugno,Nicola M. Pugno +8 more
TL;DR: This work proposes and experimentally validate an alternative approach, using the filtering and focusing properties of phononic crystals to naturally select and reflect the higher harmonics generated by nonlinear effects, enabling the realization of time-reversal procedures for nonlinear elastic source detection.