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1. Selective Actuation Enabled Multifunctional Magneto‐Mechanical Metamaterial for Programming Elastic Wave Propagation

   https://doi.org/10.1002/adfm.202422325  

   Sim, Jay; Wu, Shuai; Hwang, Sarah; Lu, Lu; Zhao, Ruike Renee (December 2024, Advanced Functional Materials)

   Abstract Active metamaterials are a type of metamaterial with tunable properties enabled by structural reconfigurations. Existing active metamaterials often achieve only a limited number of structural reconfigurations upon the application of an external load across the entire structure. Here, a selective actuation strategy is proposed for inhomogeneous deformations of magneto‐mechanical metamaterials, which allows for the integration of multiple elastic wave‐tuning functionalities into a single metamaterial design. Central to this actuation strategy is that a magnetic field is applied to specific unit cells instead of the entire metamaterial, and the unit cell can transform between two geometrically distinct shapes, which exhibit very different mechanical responses to elastic wave excitations. The numerical simulations and experiments demonstrate that the tunable response of the unit cell, coupled with inhomogeneous deformation achieved through selective actuation, unlocks multifunctional capabilities of magneto‐mechanical metamaterials such as tunable elastic wave transmittance, elastic waveguide, and vibration isolation. The proposed selective actuation strategy offers a simple but effective way to control the tunable properties and thus enhances the programmability of magneto‐mechanical metamaterials, which also expands the application space of magneto‐mechanical metamaterials in elastic wave manipulation. 

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2. 4D printed shape memory metamaterial for vibration bandgap switching and active elastic-wave guiding

   https://doi.org/10.1039/D0TC04999A  

   Li, Bing; Zhang, Chao; Peng, Fang; Wang, Wenzhi; Vogt, Bryan D.; Tan, K. T. (February 2021, Journal of Materials Chemistry C)

   null (Ed.)

   Acoustic/elastic metamaterials that rely on engineered microstructures instead of chemical composition enable a rich variety of extraordinary effective properties that are suited for various applications including vibration/noise isolation, high-resolution medical imaging, and energy harvesting and mitigation. However, the static nature of these elastic wave guides limits their potential for active elastic-wave guiding, as microstructure transformation remains a challenge to effectively apply in traditional elastic metamaterials due to the interplay of polarization and structural sensitivity. Here, a tunable, locally resonant structural waveguide is proposed and demonstrated for active vibration bandgap switching and elastic-wave manipulation between 1000–4000 Hz based on 3D printed building blocks of zinc-neutralized poly(ethylene- co -methacrylic acid) ionomer (Surlyn 9910). The ionomer exhibits shape memory behavior to enable rearrangement into new shape patterns through application of thermal stimuli that tunes mechanical performance in both space and time dimensions (4D metamaterial). The thermally induced shape-reorganization is programed to flip a series of frequency bands from passbands to bandgaps and vice versa . The continuously switched bandwidth can exceed 500 Hz. Consequently, altering the bandgap from “on” to “off” produces programmable elastic-wave propagation paths to achieve active wave guiding phenomena. An anisotropic cantilever-in-mass model is demonstrated to predict the self-adaptive dynamic responses of the printed structures with good agreement between the analytical work and experimental results. The tunable metamaterial-based waveguides illustrate the potential of 4D printed shape memory polymers in the designing and manufacturing of intelligent devices for elastic-wave control and vibration isolation. 

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3. On-Demand Noise Mitigation With Time-Modulated Active Acoustic Metamaterials

   https://doi.org/10.61782/fa.2025.0655  

   Popa, Bogdan-Ioan (December 2025, European Acoustics Association)

   It is generally accepted that active metamaterials could, in principle, address long-standing challenges in noise mitigation. However, the research of active structures capable to meet these challenges has been slow due to issues of stability and scalability. This work shows that 2D active metamaterials composed of arrangements of sensor- driver pairs can be configured to be excellent sound absorbers very well matched to the background fluid and thus scatter-free. The property is achieved by programming the metamaterial effective mass density and bulk modulus to be complex numbers with matching phases. Moreover, the metamaterials can be switched from being opaque absorbers to transparent media on very small time scales by time-modulating their effective material properties without adverse effects such as ensuing instability. Furthermore, the metamaterial unit cells are completely independent of each other thus promoting scalability. 

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4. Magneto-Mechanical Metamaterials: A Perspective

   https://doi.org/10.1115/1.4063816  

   Sim, Jay; Zhao, Ruike Renee (March 2024, Journal of Applied Mechanics)

   Abstract Magneto-mechanical metamaterials possess unique and tunable properties by adjusting their shape configurations in response to an external magnetic field. Their designs and functionalities are diverse and are utilized in a wide variety of applications, such as highly tunable elastic and electromagnetic wave filters and targeted shape morphing. In this perspective, we examine the general background of magneto-mechanical metamaterials and their diverse applications. The possible future directions in the field are also thoroughly discussed. 

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5. Extreme material parameters accessible by active acoustic metamaterials with Willis coupling

   https://doi.org/10.1121/10.0009771  

   Craig, Steven R.; Wang, Bohan; Su, Xiaoshi; Banerjee, Debasish; Welch, Phoebe J.; Yip, Mighten C.; Hu, Yuhang; Shi, Chengzhi (March 2022, The Journal of the Acoustical Society of America)

   Active acoustic metamaterials incorporate electric circuit elements that input energy into an otherwise passive medium to aptly modulate the effective material properties. Here, we propose an active acoustic metamaterial with Willis coupling to drastically extend the tunability of the effective density and bulk modulus with the accessible parameter range enlarged by at least two orders of magnitude compared to that of a non-Willis metamaterial. Traditional active metamaterial designs are based on local resonances without considering the Willis coupling that limit their accessible effective material parameter range. Our design adopts a unit cell structure with two sensor-transducer pairs coupling the acoustic response on both sides of the metamaterial by detecting incident waves and driving active signals asymmetrically superimposed onto the passive response of the material. The Willis coupling results from feedback control circuits with unequal gains. These asymmetric feedback control circuits use Willis coupling to expand the accessible range of the effective density and bulk modulus of the metamaterial. The extreme effective material parameters realizable by the metamaterials will remarkably broaden their applications in biomedical imaging, noise control, and transformation acoustics-based cloaking. 

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