Graded elastic metasurface for enhanced energy harvesting

Graded elastic metasurface for enhanced energy harvesting

In elastic wave systems, combining the powerful concepts of resonance and spatial grading within structured surface arrays enable resonant metasurfaces to exhibit broadband wave trapping, mode conversion from surface (Rayleigh) waves to bulk (shear) waves, and spatial frequency selection. Devices bu...

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Bibliographic Details
Published in:New journal of physics Vol. 22; no. 1; pp. 13013 - 13023
Main Authors: De Ponti, Jacopo M, Colombi, Andrea, Ardito, Raffaele, Braghin, Francesco, Corigliano, Alberto, Craster, Richard V
Format: Journal Article
Language:English
Published: Bristol IOP Publishing 01-01-2020
Subjects:
Amplification
Arrays
Broadband
Computer simulation
Devices
Elastic half spaces
Elastic plates
Elastic waves
Energy harvesting
Mathematical models
metamaterials
Metasurfaces
metawedge
Physics
piezoelectric materials
Piezoelectricity
rainbow trapping
Rainbows
Surface waves
Trapping
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Summary:In elastic wave systems, combining the powerful concepts of resonance and spatial grading within structured surface arrays enable resonant metasurfaces to exhibit broadband wave trapping, mode conversion from surface (Rayleigh) waves to bulk (shear) waves, and spatial frequency selection. Devices built around these concepts allow for precise control of surface waves, often with structures that are subwavelength, and utilise Rainbow trapping that separates the signal spatially by frequency. Rainbow trapping yields large amplifications of displacement at the resonator positions where each frequency component accumulates. We investigate whether this amplification, and the associated control, can be used to create energy harvesting devices; the potential advantages and disadvantages of using graded resonant devices as energy harvesters is considered. We concentrate upon elastic plate models for which the A0 mode dominates, and take advantage of the large displacement amplitudes in graded resonant arrays of rods, to design innovative metasurfaces that trap waves for enhanced piezoelectric energy harvesting. Numerical simulation allows us to identify the advantages of such graded metasurface devices and quantify its efficiency, we also develop accurate models of the phenomena and extend our analysis to that of an elastic half-space and Rayleigh surface waves.
Bibliography:NJP-110905.R1
ISSN:1367-2630
1367-2630
DOI:10.1088/1367-2630/ab6062