Topological surface wave metamaterials for robust vibration attenuation and energy harvesting

Wu, Xinyue; Jin, Yabin; Khelif, Abdelkrim; Zhuang, Xiaoying; Rabczuk, Timon; Djafari‐Rouhani, Bahram

doi:10.1080/15376494.2021.1937758

Cited by 30 publications

(5 citation statements)

References 52 publications

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“…The multifaceted capabilities of the proposed 3D metamaterial could help to improve performance in engineering applications that involve low‐frequency and multiband elastic wave control, such as vibration energy harvesters and isolators. [ 10 , 11 , 12 , 13 , 14 , 51 , 52 ] Moreover, the rich 3D, multiband, frequency‐dependent, and polarization‐dependent features of the metamaterial could be utilized to construct information‐dense phononic circuitry (i.e., elastic wave‐based, with information‐density derived from the three distinct elastic wave polarizations: two quasi‐shear and one quasi‐longitudinal) for mechanical computers, wave filters, and on‐chip devices. [ 15 , 16 , 17 , 18 , 19 , 74 ] For example, the proposed metamaterial may be used as the building block of 3D phononic circuits with multiple working channels that route waves in a layer‐dependent fashion based on the polarization and frequency of external inputs.…”

Section: Discussionmentioning

confidence: 99%

“…These so-called topological metamaterials enable low-loss transport and arbitrary directional manipulation of elastic waves via localized topological states that are protected from unwanted scattering in the presence of structural defects or disorder. [5][6][7][8][9] The remarkable capabilities and robustness of topological metamaterials have been exploited to enhance performance in technical applications that include vibration energy harvesters [10][11][12][13][14] and a mechanical information processor, [15] and have additionally inspired investigations on their potential implementation in on-chip devices [16][17][18][19] and elastic antennas. [20] Initial research concerning topological metamaterials focused on the theoretical prediction and experimental demonstration of 0D topological states in 1D mechanical structures (e.g., the wave is localized at a point in a rod) and 1D topological states in 2D mechanical structures (e.g., the wave is localized along a line waveguide in a thin plate).…”

Section: Introductionmentioning

confidence: 99%

“…These so‐called topological metamaterials enable low‐loss transport and arbitrary directional manipulation of elastic waves via localized topological states that are protected from unwanted scattering in the presence of structural defects or disorder. [ 5 , 6 , 7 , 8 , 9 ] The remarkable capabilities and robustness of topological metamaterials have been exploited to enhance performance in technical applications that include vibration energy harvesters [ 10 , 11 , 12 , 13 , 14 ] and a mechanical information processor, [ 15 ] and have additionally inspired investigations on their potential implementation in on‐chip devices [ 16 , 17 , 18 , 19 ] and elastic antennas. [ 20 ]…”

Section: Introductionmentioning

confidence: 99%

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Uncovering and Experimental Realization of Multimodal 3D Topological Metamaterials for Low‐Frequency and Multiband Elastic Wave Control

Dorin,

Khan,

Wang

2023

Advanced Science

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Topological mechanical metamaterials unlock confined and robust elastic wave control. Recent breakthroughs have precipitated the development of 3D topological metamaterials, which facilitate extraordinary wave manipulation along 2D planar and layer‐dependent waveguides. The 3D topological metamaterials studied thus far are constrained to function in single‐frequency bandwidths that are typically in a high‐frequency regime, and a comprehensive experimental investigation remains elusive. In this paper, these research gaps are addressed and the state of the art is advanced through the synthesis and experimental realization of a 3D topological metamaterial that exploits multimodal local resonance to enable low‐frequency elastic wave control over multiple distinct frequency bands. The proposed metamaterial is geometrically configured to create multimodal local resonators whose frequency characteristics govern the emergence of four unique low‐frequency topological states. Numerical simulations uncover how these topological states can be employed to achieve polarization‐, frequency‐, and layer‐dependent wave manipulation in 3D structures. An experimental study results in the attainment of complete wave fields that illustrate 2D topological waveguides and multi‐polarized wave control in a physical testbed. The outcomes from this work provide insight that will aid future research on 3D topological mechanical metamaterials and reveal the applicability of the proposed metamaterial for wave control applications.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Uncovering and Experimental Realization of Multimodal 3D Topological Metamaterials for Low‐Frequency and Multiband Elastic Wave Control

Dorin,

Khan,

Wang

2023

Advanced Science

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“…Zhou & Wan [24] proposed a new type of metamaterial with high efficiency on Rayleigh wave isolation. Besides, topology has also been introduced to the study of the performance of metamaterials on surface waves [25]. The experimental research further confirmed the value of PWBs in engineering applications [26].…”

Section: Introductionmentioning

confidence: 98%

Surface wave mitigation by periodic wave barriers under a moving load: theoretical analysis, numerical simulation and experimental validation

Ni,

Shi

2024

Phil. Trans. R. Soc. A.

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Periodic wave barriers (PWB) open a new window for vibration mitigation. However, the Doppler effect is rarely considered in most of the previous investigations on the control of ambient vibration induced by moving loads. This article reveals the significance of the speed and frequency of moving loads on surface waves, and improves the design method of PWB for ambient vibration reduction and isolation. First, the theoretical expression of the main frequency band of surface waves propagating in an elastic half-space caused by a moving load was obtained. Comparisons with the numerical results under three different types of traffic loads were also conducted and good agreement was found. Second, the theoretical expression and numerical results were verified by experimental studies. Some inherent properties of wave propagation caused by a moving load in an elastic half-space were also revealed. Third, two kinds of PWBs, i.e. periodic empty trench barrier and periodic pile barrier, were introduced to mitigate wave propagation. It has been confirmed that if the attenuation zones of PWB match the target frequency bands given by the theoretical expression, good vibration mitigation can be achieved. This article is part of the theme issue ‘Current developments in elastic and acoustic metamaterials science (Part 1)’.

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“…In order to address this issue of several redundant piezo-electric materials, the concept of edge state diatomic periodic chain is introduced in this paper. Edge-state metamaterials localize the energy at the point of asymmetry and the band transition mechanism gives rise to the existence of interface mode (Chen et al, 2018;Ni and Shi, 2022;Pal et al, 2018Pal et al, , 2019Wu et al, 2021b). Analysis of this phenomena is widely studied in relation to topological insulators (Darabi and Leamy, 2019;Xia et al, 2017) and wave guides (Ma et al, 2018;Miniaci and Pal, 2021;Yin et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Energy harvesting using the edge-state phenomena

Baxy

Banerjee

2023

Journal of Intelligent Material Systems and Structures

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Diatomic chain consisting of spring-mass system forms an attenuation bandgap due to the formation of the standing wave when the wavelength matches with the periodicity, known as Bragg-scattering. Edge-state phenomenon can be obtained by breaking the periodicity of the diatomic chain. Owing to this edge state phenomenon, the waves, and in turn the energy, is localized at the point of the asymmetry. In this work, an efficient vibrational energy harvesting technique is proposed exploiting this edge-state energy localization by inserting piezo-electric harvester at the junction of the asymmetry. To illustrate the performance of the proposed harvester under the broad-band noise, voltage-frequency curve for three different diatomic chain configurations, having same mass and stiffness, are analyzed. The performance metric, defined as the area under the voltage-frequency curve, shows 21.5 times higher performance can be obtained just by breaking the symmetry of a conventional diatomic chain. As it is also observed that the attenuation properties of the symmetric and asymmetric chain remain same; thus, the proposed edge-state energy harvester has a significant promise toward simultaneous energy harvesting and vibration control.

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Topological surface wave metamaterials for robust vibration attenuation and energy harvesting

Cited by 30 publications

References 52 publications

Uncovering and Experimental Realization of Multimodal 3D Topological Metamaterials for Low‐Frequency and Multiband Elastic Wave Control

Uncovering and Experimental Realization of Multimodal 3D Topological Metamaterials for Low‐Frequency and Multiband Elastic Wave Control

Surface wave mitigation by periodic wave barriers under a moving load: theoretical analysis, numerical simulation and experimental validation

Energy harvesting using the edge-state phenomena

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