Tunable Lamb wave band gaps in two-dimensional magnetoelastic phononic crystal slabs by an applied external magnetostatic field

Zhou, Changjiang; Sai, Yi; Chen, Jiujiu

doi:10.1016/j.ultras.2016.05.023

Cited by 26 publications

(7 citation statements)

References 29 publications

(35 reference statements)

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“…These changes are effectively analogous to reducing the 'stiffness' in a branching mass-spring system, which may be used as an idealized model for studying the mechanism of local resonance band-gap formation [43][44][45]. The shapes of the deposited resonators (cylindrical pillar, square rod [46][47][48][49][50], sphere [51], spiral [52] or Gaussian surface [53]) and the lattice symmetry of the periodic arrangement (triangular [54][55][56], square [54][55][56][57][58], hexagonal [57], honeycomb [54,58], hybrid [59,60], or random [61,62]) have direct impact on the properties of the engineered local resonance band gap, such as its width and position in the frequency domain. Having pillars on both sides of a plate provides an additional avenue for enriching the design space [63][64][65][66][67].…”

Section: General Introductionmentioning

confidence: 99%

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Physics of surface vibrational resonances: pillared phononic crystals, metamaterials, and metasurfaces

et al. 2021

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The introduction of engineered resonance phenomena on surfaces has opened a new frontier in surface science and technology. Pillared phononic crystals, metamaterials, and metasurfaces are an emerging class of artificial structured materials, featuring surfaces, that consist of pillars-or branching substructures-standing on a substrate or a plate. A pillared phononic crystal exhibits Bragg band gaps while a pillared metamaterial may feature both Bragg gaps and local-resonance hybridization gaps. These two band-gap phenomena, along with other unique wave dispersion characteristics, have been exploited for a variety of applications spanning a range of length scales and covering multipe disciplines in applied physics and engineering. The placement of pillars on a semi-infinite surface has similarly provided new avenues for the control and manipulation of wave propagation, including Rayleigh and Love waves along the surface of substrates, as well as Lamb waves in plates-for frequencies ranging from Hz to several GHz. Even a finite placement of pillars along specific directions on a surface has been shown to offer unique functionality, such as steering a wavefront in the subwavelength regime. At the nanoscale, pillared membranes have been investigated and it was shown that atomic-scale resonances-stemming from the nanopillars-alter the fundamental nature of conductive thermal transport by reducing the group velocities and generating mode localization across the entire spectrum well into the THz regime. In this article, we first overview the history and development of pillared materials, then provide a detailed synopsis of a selection of key research topics that involve the utilization of pillars in different contexts. The following sections present a review of different configurations, properties, and 2 characteristics, namely: (i) fundamental vibrational and propagation properties of pillared plates; (ii) metamaterial phenomena in pillared plates including the opening of low and wide hybridization band gaps as well as super-resolution focusing; (iii) pillared metasurfaces and their wave steering functions;(iv) topologically protected phononic edge states in pillared plates; and (v) nanophononic metamaterials in the form of pillared membranes exhibiting exceptionally low in-plane thermal conductivity. Finally, we conclude by providing a short summary on the salient properties of pillared materials and structures and outlining some perspectives on the state of the field and its promise for further future development.

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Section: General Introductionmentioning

confidence: 99%

“…These changes are effectivity analogous to reducing the "stiffness" in a branching mass-spring system, which may be used as an idealized model for studying the mechanism of local resonance band-gap formation [35][36][37]. The shape of the deposited resonators (cylindrical pillar, square rod [7,[38][39][40][41], sphere [42], spiral [43] or…”

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confidence: 99%

Physics of surface vibrational resonances: pillared phononic crystals, metamaterials, and metasurfaces

et al. 2021

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“…There is an increased interest in developing a comprehensive framework for magneto-elastic phononic crystals with magnetostrictive materials. [15][16][17][18][19][20][21][22] It should be noted that the nonlinear magneto-mechanical coupling characteristic of magnetostrictive component is critical to tune band structures for magnetoelastic PCs. A series of comprehensive studies have been conducted to consider the multi-field coupling effect, which are beneficial to the design and application of smart PC devices.…”

Section: Supplementary Materials For This Article Is Available Onlinementioning

confidence: 99%

Tunability of hysteresis-dependent band gaps in a two-dimensional magneto-elastic phononic crystal using magnetic and stress loadings

Zhang

Gao

2019

Appl. Phys. Express

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A quasistatic hysteresis model is established to investigate the performance of elastic wave propagation in two dimensional magneto-elastic phononic crystals (PCs) with the nonlinear magneto-mechanical coupling hysteretic constitutive behavior of magnetostrictive materials when subjected to magnetic field and pre-stress. Through the example of Terfenol-D/epoxy PCs, it is revealed that the characteristics of band structures are hysteresis-dependent and remarkably affected by pre-stress due to the nature of the hysteresis behavior for Terfenol-D. Consequently, the study of hysteresis induced band structures in magneto-elastic PCs is significant and essential for intelligent regulation of phononic devices in engineering.

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“…PCs have many applications, such as vibration isolation technology [18][19][20][21][22] , acoustic barriers/filters [23][24][25] , noise suppression devices [26][27] , surface acoustic devices 28 , architectural design 29 , sound shields 30 , acoustic diodes 31 , elastic metamaterials [21][22]25,27,32 and thermal metamaterials [33][34][35][36][37][38][39] . There are also smart PCs that have been studied, such as piezoelectric [40][41][42][43][44][45][46][47][48][49][50][51][52][53][54] , piezomagnetic [55][56][57][58] and magnetoelectroelastic 14,[59][60][61]…”

Section: Introductionmentioning

confidence: 99%

Complete Band Gaps in Nano-Piezoelectric Phononic Crystals

Miranda

Santos

2017

Mat. Res.

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We study the band structure of elastic waves propagating in a nano-piezoelectric phononic crystal consisting of a polymeric matrix reinforced by BaTiO 3 inclusions in square, rectangular, triangular, honeycomb and Kagomé lattices. We also investigate the influence of inclusion cross section geometrycircular, hollow circular, square and rotated square with a 45º angle of rotation with respect to x and y axes. Plane wave expansion method is used to solve the governing equations of motion of a piezoelectric solid based on classical elasticity theory, ignoring nanoscopic size effects, considering two-dimensional periodicity and wave propagation in the xy plane. Complete band gaps between XY and Z modes are observed for all inclusions and the best performance is for circular inclusion in a triangular lattice. Piezoelectricity influences significantly the band gaps for hollow circular inclusion in lower frequencies. We suggest that nano-piezoelectric phononic crystals are feasible for elastic vibration management in GHz.

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Tunable Lamb wave band gaps in two-dimensional magnetoelastic phononic crystal slabs by an applied external magnetostatic field

Cited by 26 publications

References 29 publications

Physics of surface vibrational resonances: pillared phononic crystals, metamaterials, and metasurfaces

Physics of surface vibrational resonances: pillared phononic crystals, metamaterials, and metasurfaces

Tunability of hysteresis-dependent band gaps in a two-dimensional magneto-elastic phononic crystal using magnetic and stress loadings

Complete Band Gaps in Nano-Piezoelectric Phononic Crystals

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