Breaking the barriers: advances in acoustic functional materials

Ge, Hao; Yang, Min; Ma, Chu; Lu, Ming‐Hui; Chen, Yanfeng; Fang, Nicholas X.; Sheng, Ping

doi:10.1093/nsr/nwx154

Cited by 172 publications

(66 citation statements)

References 215 publications

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“…By adjusting the geometrical size and shape of structures, acoustic metamaterials can be used for noise attenuation purpose over a specific pre-designed and tunable frequency range. The fundamental concept of acoustic metamaterials is extensively discussed in previously published review articles [26][27][28][29][30][31][32][33][34][35][36]. In this article, we have explored the viability of acoustic metamaterials for architectural and urban noise mitigation applications.…”

Section: Sourcementioning

confidence: 99%

The Present and Future Role of Acoustic Metamaterials for Architectural and Urban Noise Mitigations

Kumar

Lee

2019

Acoustics

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Owing to a steep rise in urban population, there has been a continuous growth in construction of buildings, public or private transport like cars, motorbikes, trains, and planes at a global level. Hence, urban noise has become a major issue affecting the health and quality of human life. In the current environmental scenario, architectural acoustics has been directed towards controlling and manipulating sound waves at a desired level. Structural engineers and designers are moving towards green technologies, which may help improve the overall comfort level of residents. A variety of conventional sound absorbing materials are being used to reduce noise, but attenuation of low-frequency noise still remains a challenge. Recently, acoustic metamaterials that enable low-frequency sound manipulation, mitigation, and control have been widely used for architectural acoustics and traffic noise mitigation. This review article provides an overview of the role of acoustic metamaterials for architectural acoustics and road noise mitigation applications. The current challenges and prominent future directions in the field are also highlighted.

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Section: Sourcementioning

confidence: 99%

The Present and Future Role of Acoustic Metamaterials for Architectural and Urban Noise Mitigations

Kumar

Lee

2019

Acoustics

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“…Metasurfaces, as a two‐dimensional (2D) equivalent of bulk metamaterials, have attracted numerous research efforts in recent years due to their powerful ability to control classical waves such as electromagnetic, acoustic, and elastic waves. In acoustics, metasurfaces offer a new paradigm for manipulating wave propagation, engineering acoustic wavefront, and realizing various interesting functions including acoustic cloaking, holographic rendering, and acoustic communication . These functions are enabled by the fundamental subwavelength building blocks (unit cells) of metasurfaces.…”

Section: Introductionmentioning

confidence: 99%

Programmable Acoustic Metasurfaces

Tian

Shen

et al. 2019

Adv Funct Materials

140

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Metasurfaces open up unprecedented potential for wave engineering using subwavelength sheets. However, a severe limitation of current acoustic metasurfaces is their poor reconfigurability to achieve distinct functions on demand. Here a programmable acoustic metasurface that contains an array of tunable subwavelength unit cells to break the limitation and realize versatile two-dimensional wave manipulation functions is reported. Each unit cell of the metasurface is composed of a straight channel and five shunted Helmholtz resonators, whose effective mass can be tuned by a robust fluidic system. The phase and amplitude of acoustic waves transmitting through each unit cell can be modulated dynamically and continuously. Based on such mechanism, the metasurface is able to achieve versatile wave manipulation functions, by engineering the phase and amplitude of transmission waves in the subwavelength scale. Through acoustic field scanning experiments, multiple wave manipulation functions, including steering acoustic waves, engineering acoustic beams, and switching on/off acoustic energy flow by using one design of metasurface are visually demonstrated. This work extends the metasurface research and holds great potential for a wide range of applications including acoustic imaging, communication, levitation, and tweezers.

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“…2e, apart from the gap of C = 1, other gaps with C = −1, −2, 2, 3 are typically narrow and appear at high frequencies, so designing setups where these gaps are wide and are formed at low frequencies is particularly relevant from experimental point of view. Last but not least, the concept of topology-protected nonlinear frequency mixing is universal in that it applies not only to photonics, but also to plasmonics [32][33][34][35], phononics [36][37][38], magnonics [39][40][41], and metamaterials [42,43], thus we expect that our work will generate a broad impact.…”

Section: Resultsmentioning

confidence: 99%

Nonlinear one-way edge-mode interactions for frequency mixing in topological photonic crystals

2020

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Topological photonics aims to utilize topological photonic bands and corresponding edge modes to implement robust light manipulation, which can be readily achieved in the linear regime of light-matter interaction. Importantly, unlike solid state physics, the common test bed for new ideas in topological physics, topological photonics provide an ideal platform to study wave mixing and other nonlinear interactions. These are well-known topics in classical nonlinear optics but largely unexplored in the context of topological photonics. Here, we investigate nonlinear interactions of one-way edge-modes in frequency mixing processes in topological photonic crystals. We present a detailed analysis of the band topology of two-dimensional photonic crystals with hexagonal symmetry and demonstrate that nonlinear optical processes, such as second-and third-harmonic generation can be conveniently implemented via one-way edge modes of this setup. Moreover, we demonstrate that more exotic phenomena, such as slow-light enhancement of nonlinear interactions and harmonic generation upon interaction of backwardpropagating (left-handed) edge modes can also be realized. Our work opens up new avenues towards topologyprotected frequency mixing processes in photonics.One of the most important developments in condensed matter physics in the past decades is the discovery of topological insulating materials [1,2]. These materials feature gapped bulk but gapless edge modes, which propagate unidirectionally along the system edge and are immune to local disorder, thus opening a promising avenue towards robust wave manipulation protected by topology. Inspired by this development, the emerging field of topological photonics aims to extend these topology related ideas to the realm of photonics [3][4][5][6], which holds great promises for innovative optical devices by exploiting robust, scattering-free light propagation and manipulation. As the concept of energy band exists at the single particle level both in condensed matter physics and photonics, the goal of realizing photonic topological insulators can be readily achieved in the linear regime of light matter interaction. Indeed, topological phenomena of electromagnetic waves in a linear medium can be understood by mapping Maxwell equations to the Schrödinger equation [7,8].Photonics, however, has several features not present in solid-state physics. For example, optical gain and loss can be utilized to implement non-Hermitian photonics based on parity-time symmetry [9]. The recently realized topological insulator laser demonstrates the power of this new ingredient and could deepen our understanding of the interplay between non-hermiticity and topology in active optical systems k ω ω 0 Ω 2 = 2ω 0 Ω 3 = 3ω 0 y x z a b FIG. 1. Nonlinear one-way edge mode interaction in 2D topological photonic crystals. a, Schematic band structure showing the emergent edge modes due to the nontrivial topology of the bulk frequency bands. The edge modes can couple via SHG and THG frequency mixing processes. b, Real ...

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Breaking the barriers: advances in acoustic functional materials

Cited by 172 publications

References 215 publications

The Present and Future Role of Acoustic Metamaterials for Architectural and Urban Noise Mitigations

The Present and Future Role of Acoustic Metamaterials for Architectural and Urban Noise Mitigations

Programmable Acoustic Metasurfaces

Nonlinear one-way edge-mode interactions for frequency mixing in topological photonic crystals

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