Experimental proof of emergent subharmonic attenuation zones in a nonlinear locally resonant metamaterial

Zega, Valentina; Silva, Priscilla B.; Geers, M.G.D.; Kouznetsova, V Varvara

doi:10.1038/s41598-020-68894-3

Cited by 21 publications

(7 citation statements)

References 51 publications

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“…Beyond the results presented herein, multiple opportunities are identified for future studies such as stability analyses [49,59], the forced response behavior, and possibilities for localization transitions between edge states and discrete breathers induced by the amplitude of motion. Additionally, the extension of these concepts to continuous non-linear elastic metamaterials [74] may define a fruitful endeavor, leading towards experimental studies [75].…”

Section: Discussionmentioning

confidence: 99%

Amplitude-dependent edge states and discrete breathers in nonlinear modulated phononic lattices

Rosa,

Leamy,

Ruzzene

2023

New J. Phys.

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We investigate the spectral properties of one-dimensional spatially modulated nonlinear phononic lattices, and their evolution as a function of amplitude. In the linear regime, the stiffness modulations define a family of periodic and quasiperiodic lattices whose bandgaps host topological edge states localized at the boundaries of finite domains. With cubic nonlinearities, we show that edge states whose eigenvalue branch remains within the gap as amplitude increases remain localized, and therefore appear to be robust with respect to amplitude. In contrast, edge states whose corresponding branch approaches the bulk bands experience de-localization transitions. These transitions are predicted through continuation studies on the linear eigenmodes as a function of amplitude, and are confirmed by direct time domain simulations on finite lattices. Through our predictions, we also observe a series of amplitude-induced localization transitions as the bulk modes detach from the nonlinear bulk bands and become discrete breathers that are localized in one or more regions of the domain. Remarkably, the predicted transitions are independent of the size of the finite lattice, and exist for both periodic and quasiperiodic lattices. These results highlight the co-existence of topological edge states and discrete breathers in nonlinear modulated lattices. Their interplay may be exploited for amplitude-induced eigenstate transitions, for the assessment of the robustness of localized states, and as a strategy to induce discrete breathers through amplitude tuning.

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Section: Discussionmentioning

confidence: 99%

Amplitude-dependent edge states and discrete breathers in nonlinear modulated phononic lattices

Rosa,

Leamy,

Ruzzene

2023

New J. Phys.

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“…In addition, harmonic tuning mechanisms have also been realized by including nonlinearity in PnCs and AMMs, such as subharmonic generation, where a fraction of the propagating energy is transferred to frequencies that are fractions of the exciting frequency, preventing wave propagation when generated subharmonic frequencies are located in a bandgap, [157,158] or vice versa, [159] and zero-frequency generation, which is due to wave self-interactions with asymmetric nonlinearity that causes rectification of an excited wave, leading to unit cell displacements from their original equilibrium position upon wave propagation through them [160,161] and the expansion of phononic systems. [161][162][163] Among all the harmonic tuning mechanisms, the generation of higher harmonics via nonlinearity [164] has been investigated to a greater extent in the phononics community.…”

Section: Nonlinear Effectmentioning

confidence: 99%

Phonon Engineering of Micro‐ and Nanophononic Crystals and Acoustic Metamaterials: A Review

2022

Small Science

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Figure 2. a,e) Experimental specimens of a regular Kagome lattice (a) and a topological Kagome lattice (e). b,f ) Isofrequency contours (first phaseconstant surface in the first Brillouin zone) of regular (b) and topological (f ) Kagome lattices calculated from FEA. c,g) Group velocity isofrequency contours (frequency increasing from dark red to bright yellow) highlighting symmetric or asymmetric directivity of regular (c) and topological (g) lattices. d,h) Snapshots of experimentally acquired wave fields in regular (d) and topological (h) lattices, confirming symmetric or asymmetric propagation. Colors denotes the magnitude of the scan point velocities, normalized by the largest value at the considered instants. a-h) Reproduced with permission. [40]

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“…The potentialities of micro (and nano) sensors and actuators are often limited by standard fabrication technologies strictly related to planar lithographic techniques. The lack of true three-dimensional fabrication processes in MEMS has prevented, so far, the development of devices in which fully 3D micro-structures can enhance sensitivity and actuation performances or the exploitation of new physical principles to govern signals [2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Microstructured Phononic Crystal Isolates from Ultrasonic Mechanical Vibrations

et al. 2022

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The functioning of many micro-electromechanical devices with parts oscillating at high frequencies require isolation from external vibration. Phononic crystals, presenting band-gaps in the dispersion spectrum, i.e., interval of frequency in which propagating waves are attenuated, can provide an effective solution for vibration shielding at the microscale. In the present work, we design—through numerical simulations—a 3D phononic crystal with a micrometric unit cell able to work as vibration isolator for a micro system. We exploit the direct writing technique based on two-photon polymerization to realize three prototypes of different dimensions. Experimental measurements performed with a Michelson interferometer demonstrate the effectiveness of the proposal.

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Experimental proof of emergent subharmonic attenuation zones in a nonlinear locally resonant metamaterial

Cited by 21 publications

References 51 publications

Amplitude-dependent edge states and discrete breathers in nonlinear modulated phononic lattices

Amplitude-dependent edge states and discrete breathers in nonlinear modulated phononic lattices

Phonon Engineering of Micro‐ and Nanophononic Crystals and Acoustic Metamaterials: A Review

Microstructured Phononic Crystal Isolates from Ultrasonic Mechanical Vibrations

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