2017
DOI: 10.1016/j.jmps.2017.02.006
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Dispersive wave propagation in two-dimensional rigid periodic blocky materials with elastic interfaces

Abstract: Dispersive waves in two-dimensional blocky materials with periodic microstructure made up of equal rigid units having polygonal centro-symmetric shape with mass and gyroscopic inertia, connected each other through homogeneous linear interfaces, have been analysed. The acoustic behavior of the resulting discrete Lagrangian model has been obtained through a Floquet-Bloch approach. From the resulting eigenproblem derived by the Euler-Lagrange equations for harmonic wave propagation, two acoustic branches and an o… Show more

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Cited by 42 publications
(37 citation statements)
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“…According to a Lagrangian mechanical formulation, the i-th block is assumed to undergo a transverse displacement i v and rotation i  so that the equations of free motion are written (see for reference Bacigalupo and Gambarotta, 2017) Tracking the dependence on the wavenumber k in the domain   0,  allows to completely assess the Floquet-Bloch spectrum of the periodic system (Brillouin, 1946). The dispersion function may be represented in terms of the non-dimensional circular frequency , which cannot be identified a priori as limit points of the acoustic or optical branch.…”
Section: Fig 1 the Stack Of Rigid Blocks And The Generalized Displamentioning
confidence: 99%
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“…According to a Lagrangian mechanical formulation, the i-th block is assumed to undergo a transverse displacement i v and rotation i  so that the equations of free motion are written (see for reference Bacigalupo and Gambarotta, 2017) Tracking the dependence on the wavenumber k in the domain   0,  allows to completely assess the Floquet-Bloch spectrum of the periodic system (Brillouin, 1946). The dispersion function may be represented in terms of the non-dimensional circular frequency , which cannot be identified a priori as limit points of the acoustic or optical branch.…”
Section: Fig 1 the Stack Of Rigid Blocks And The Generalized Displamentioning
confidence: 99%
“…In fact, to obtain low-frequency Bragg gaps, heavy inclusions, low stiffness and large cell size are needed, which may be not suitable for practical purposes. Alternatively, band gaps may be obtained by including local resonators in the periodic material, whose role is to impede wave propagation around their resonance frequency by transferring the vibrational energy to the resonator (see for reference Huang and Sun, 2010, Craster and Guenneau, 2012, Baravelli and Ruzzene, 2013, Bacigalupo and Gambarotta, 2017, Beli and Ruzzene, 2018, Deng et al, 2018. In this case, low-frequency band gaps may be obtained, even if heavy resonators and low stiffness cells are required to get wide stop-bands.…”
Section: Introductionmentioning
confidence: 99%
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“…This limit behaviour is typical of first-order continua and is consistent with the possibility to approximate the acoustic dispersion surfaces of the beam lattice material with those of a first-order homogenized continuum. For shorter wavelengths the dispersion effects are increasingly important and better approximations of the material spectrum are achievable by homogenization in non-local continua [51,66]. The boundary of the Brillouin zone B, defining the limit of short wavelengths, is identically featured by vanishing group velocity, but finite not null phase velocities.…”
Section: Energy Velocitymentioning
confidence: 99%
“…Finally, a 2D piezo-elasto-dynamic dispersion analysis adopting the Floquet-Bloch decomposition is performed. We extend to piezoelectric materials the analysis of chiral honeycomb lattices to evaluate the properties of the dispersion functions of waves propagating in different directions and to detect the band gaps characterizing the material, [22,[40][41][42][43][44][45][46]. The paper is organized as follows.…”
Section: Introductionmentioning
confidence: 99%