Rayleigh–Bloch, topological edge and interface waves for structured elastic plates

Galvanised by the emergent fields of metamaterials and topological wave physics, there is currently much interest in controlling wave propagation along structured arrays, and interfacial waves between geometrically different crystal arrangements. We model array and interface waves for structured thi...

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Bibliographic Details
Published in:Wave motion 2019-03, Vol.86, p.162-174
Main Authors: Chaplain, G.J., Makwana, M.P., Craster, R.V.
Format: Article
Language:English
Subjects:
Arrays
Computer simulation
Crystal structure
Crystals
Decay
Dispersion curve analysis
Elastic plates
Galerkin method
Galerkin spectral method
Hermite functions
Kirchhoff–Love plate theory
Metamaterials
Photonic crystals
Propagation
Rainbows
Rayleigh Bloch modes
Rayleigh number
Surface waves
Topology
Valleytronics
Wave physics
Wave propagation
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Summary:Galvanised by the emergent fields of metamaterials and topological wave physics, there is currently much interest in controlling wave propagation along structured arrays, and interfacial waves between geometrically different crystal arrangements. We model array and interface waves for structured thin elastic plates, so-called platonic crystals, that share many analogies with their electromagnetic and acoustic counterparts, photonic and phononic crystals, and much of what we present carries across to those systems. These crystals support several forms of edge or array-guided modes, that decay perpendicular to their direction of propagation. To rapidly, and accurately, characterise these modes and their decay we develop a spectral Galerkin method, using a Fourier–Hermite basis, to provide highly accurate dispersion diagrams and mode-shapes, that are confirmed with full scattering simulations. We illustrate this approach using Rayleigh Bloch modes, and generalise high frequency homogenisation, along a line array, to extract the envelope wavelength along the array. Rayleigh–Bloch modes along graded arrays of rings of point masses are investigated and novel forms of the rainbow trapping effect and wave hybridisation are demonstrated. Finally, the method is used to investigate the dispersion curves and mode-shapes of interfacial waves created by geometrical differences in adjoining media. •A highly effective numerical scheme is presented that extracts guided wave modes.•HFH developed in reciprocal space.•Scheme is illustrated for well known RB waves.•Also illustrated for topical topological waves.•Used as a design tool for graded structures, displaying tapping and hybridisation.
ISSN:0165-2125
1878-433X
DOI:10.1016/j.wavemoti.2019.01.008