Magneto‐Mechanical Metamaterials with Widely Tunable Mechanical Properties and Acoustic Bandgaps

Montgomery, S. Macrae; Wu, Shu-Pao; Xiao, Kun; Armstrong, Connor D.; Zemelka, Cole; Ze, Qiji; Zhang, Rundong; Zhao, Ruike Renee; Hu, Qi

doi:10.1002/adfm.202005319

Cited by 130 publications

(127 citation statements)

References 44 publications

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“…The properties and functionalities of the soft material systems are related to the configurations and deformations of the structures. With the ability to undergo large deformations as programmed, the mechanical [ 46 , 80 , 107 , 121 ], optical [ 112 , 122 ], and acoustic properties [ 120 , 123 – 127 ], or wettability [ 106 , 119 ] of magnetic soft composites are actively tunable under the applied magnetic field. For instance, an array of microplates embedded with aligned Fe microparticles possess a superhydrophobic or hydrophilic surface on each side of the plates ( figure 5(d) [ 119 ]).…”

Section: Function and Operation Of Magnetic Soft Materialsmentioning

confidence: 99%

“…As shown in figure 5(e) , by designing structure geometries and magnetization distributions, an auxetic metamaterial shows actively controllable stiffness down to 20% of the initial stiffness under the external magnetic field [ 46 ]. With a considerable area shrinkage, both the number and the magnitude of the acoustic bandgaps can be tuned by tailoring the magnetic field [ 120 ]. Figure 5(f) illustrates an active metamaterial system with the structural integration of magnetic soft materials and magnetic SMPs.…”

Section: Function and Operation Of Magnetic Soft Materialsmentioning

confidence: 99%

“…(e) Auxetic metamaterials with actively tunable stiffness (Left: Adapted with permission from [ 46 ]. Copyright 2019, American Chemical Society) and acoustic bandgaps (Right: Adapted with permission from [ 120 ]. Copyright 2020, Wiley).…”

Section: Figurementioning

confidence: 99%

See 2 more Smart Citations

Multifunctional magnetic soft composites: a review

et al. 2020

Multifunct. Mater.

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155

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Magnetically responsive soft materials are soft composites where magnetic fillers are embedded into soft polymeric matrices. These active materials have attracted extensive research and industrial interest due to their ability to realize fast and programmable shape changes through remote and untethered control under the application of magnetic fields. They would have many high-impact potential applications in soft robotics/devices, metamaterials, and biomedical devices. With a broad range of functional magnetic fillers, polymeric matrices, and advanced fabrication techniques, the material properties can be programmed for integrated functions, including programmable shape morphing, dynamic shape deformation-based locomotion, object manipulation and assembly, remote heat generation, as well as reconfigurable electronics. In this review, an overview of state-of-the-art developments and future perspectives in the multifunctional magnetically responsive soft materials is presented.

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Section: Function and Operation Of Magnetic Soft Materialsmentioning

confidence: 99%

Section: Function and Operation Of Magnetic Soft Materialsmentioning

confidence: 99%

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Multifunctional magnetic soft composites: a review

et al. 2020

Multifunct. Mater.

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178

155

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“…Our approach is fundamentally different from and is complementary to recent developments based on poroelasticity ( 29 ) and magnetoelasticity ( 30 ). In these works, multifunctionality is achieved through elaborate actuation multiphysics couplings and via loading in the bulk: The loading is exerted on the bulk by external fields, such as a chemical potential or a magnetic field.…”

Section: Discussionmentioning

confidence: 99%

Oligomodal metamaterials with multifunctional mechanics

Bossart

Dykstra

Laan

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Mechanical metamaterials are artificial composites that exhibit a wide range of advanced functionalities such as negative Poisson’s ratio, shape shifting, topological protection, multistability, extreme strength-to-density ratio, and enhanced energy dissipation. In particular, flexible metamaterials often harness zero-energy deformation modes. To date, such flexible metamaterials have a single property, for example, a single shape change, or are pluripotent, that is, they can have many different responses, but typically require complex actuation protocols. Here, we introduce a class of oligomodal metamaterials that encode a few distinct properties that can be selectively controlled under uniaxial compression. To demonstrate this concept, we introduce a combinatorial design space containing various families of metamaterials. These families include monomodal (i.e., with a single zero-energy deformation mode); oligomodal (i.e., with a constant number of zero-energy deformation modes); and plurimodal (i.e., with many zero-energy deformation modes), whose number increases with system size. We then confirm the multifunctional nature of oligomodal metamaterials using both boundary textures and viscoelasticity. In particular, we realize a metamaterial that has a negative (positive) Poisson’s ratio for low (high) compression rate over a finite range of strains. The ability of our oligomodal metamaterials to host multiple mechanical responses within a single structure paves the way toward multifunctional materials and devices.

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“…Miniaturizing such structures to be comparable to the small scale in natural and/or human-engineered living systems such as arteries (1∼10 mm) (3), early-stage lesions (4), and organoids (∼1 mm) (5), and in minimally invasive surgeries (4) could broaden their applications in biomedical, healthcare, and electronic devices (6,7). Recent advances in manufacture, fabrication, and assembly techniques enable the use of materials that respond to irradiation (8)(9)(10)(11)(12), magnetic field (13)(14)(15)(16)(17)(18)(19)(20)(21), electric field (22)(23)(24)(25)(26)(27), electromagnetic field (28,29), heat (17,(30)(31)(32)(33)(34)(35)(36), chemicals (37,38), and pressures (39,40) to remotely actuate large structural deformations (41)(42)(43)(44)(45)(46)(47). For example, the three-dimensional (3D) printing technique of programmed ferromagnetic domains developed by Kim et al…”

mentioning

confidence: 99%

Rapidly deployable and morphable 3D mesostructures with applications in multimodal biomedical devices

Zhang

Shen

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Structures that significantly and rapidly change their shapes and sizes upon external stimuli have widespread applications in a diversity of areas. The ability to miniaturize these deployable and morphable structures is essential for applications in fields that require high-spatial resolution or minimal invasiveness, such as biomechanics sensing, surgery, and biopsy. Despite intensive studies on the actuation mechanisms and material/structure strategies, it remains challenging to realize deployable and morphable structures in high-performance inorganic materials at small scales (e.g., several millimeters, comparable to the feature size of many biological tissues). The difficulty in integrating actuation materials increases as the size scales down, and many types of actuation forces become too small compared to the structure rigidity at millimeter scales. Here, we present schemes of electromagnetic actuation and design strategies to overcome this challenge, by exploiting the mechanics-guided three-dimensional (3D) assembly to enable integration of current-carrying metallic or magnetic films into millimeter-scale structures that generate controlled Lorentz forces or magnetic forces under an external magnetic field. Tailored designs guided by quantitative modeling and developed scaling laws allow formation of low-rigidity 3D architectures that deform significantly, reversibly, and rapidly by remotely controlled electromagnetic actuation. Reconfigurable mesostructures with multiple stable states can be also achieved, in which distinct 3D configurations are maintained after removal of the magnetic field. Demonstration of a functional device that combines the deep and shallow sensing for simultaneous measurements of thermal conductivities in bilayer films suggests the promising potential of the proposed strategy toward multimodal sensing of biomedical signals.

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Magneto‐Mechanical Metamaterials with Widely Tunable Mechanical Properties and Acoustic Bandgaps

Cited by 130 publications

References 44 publications

Multifunctional magnetic soft composites: a review

Multifunctional magnetic soft composites: a review

Oligomodal metamaterials with multifunctional mechanics

Rapidly deployable and morphable 3D mesostructures with applications in multimodal biomedical devices

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