Mechanical Deformation Induced Circular Dichroism in Propeller‐Shaped Terahertz Metamaterials

Han, Dong; Zhang, Liuyang; Becton, Matthew; Chen, Xuefeng

doi:10.1002/admt.202100161

Cited by 10 publications

(10 citation statements)

References 54 publications

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“…[27][28][29] To broaden the modulation range, 3D assembly technique is implemented to transform the planar precursor selectively bonded on the pre-stretched substrate into 3D chiral meta-atoms by releasing the stress to eventually tune the spindependent transmission. [30][31][32] Despite of simple composition and superior mechanical characteristics, these mechanically reconfigurable metamaterials are only restricted to tune the spectral responses.…”

Section: Introductionmentioning

confidence: 99%

Kirigami‐Inspired Planar Deformable Metamaterials for Multiple Dynamic Electromagnetic Manipulations

Han

Liu

et al. 2023

Laser & Photonics Reviews

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The Kirigami technique has recently inspired the design of reconfigurable electromagnetic metamaterials that can be easily realized by embedding a patterned cutting array into a supportive substrate. However, these existing designs mainly focus on the 2D‐to‐3D transformable morphology that induces the modulation of the spectral responses. This work proposes a kirigami‐based planar reconfiguration mechanism and extends advanced applications in the dynamic near‐field imaging and tunable double‐foci metalens. These extraordinary tunabilities originate from three meta‐atoms that can be mutually transformed into the morphologies with non‐chirality and opposite chirality under the tensile strain. By utilizing the transmittance characteristics of reconfigurable meta‐atoms, the metamaterial is constructed to achieve three‐foldable near‐field displays and a longitudinal double‐foci metalens empowered with tunable focusing length and intensity ratio. Two anisotropic chiral meta‐atoms in deformed states that possess overwhelming transmittance difference of circularly cross‐polarized components to magnify the focusing intensity ratio of two foci for the proposed metalens are further proposed. The exhibited observations provide typical examples of a wide spectrum of applications of the kirigami‐based reconfiguration mechanism, and it may pave the avenue to spark manifold functional devices for applicable electromagnetic manipulations such as multifunctional hologram display, dynamic beam shaping, and steering, as well as the conformal design of meta‐devices.

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Section: Introductionmentioning

confidence: 99%

Kirigami‐Inspired Planar Deformable Metamaterials for Multiple Dynamic Electromagnetic Manipulations

Han

Liu

et al. 2023

Laser & Photonics Reviews

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“…Zhang et al [34] proposed a 3D antenna with reconfigurable resonant frequency by applying stretching strains in different orders on substrate to obtain multistability of the 3D assemblies. Han et al [35,36] introduced a 3D mechanically reconfigured chiral metamaterial prepared by compressing origami structures after releasing prestrain and capable of dynamically tuning circular dichroism by active manipulation. Pan et al [37] proposed a flexible FSS with serpentine metal stripe unit sputtered on a flexible substrate polyimide that can be wrapped around the cylindrical surface with no drift in resonant frequency when the bending angle is below π.…”

Section: Introductionmentioning

confidence: 99%

“…Han et al. [ 35,36 ] introduced a 3D mechanically reconfigured chiral metamaterial prepared by compressing origami structures after releasing prestrain and capable of dynamically tuning circular dichroism by active manipulation. Pan et al.…”

Section: Introductionmentioning

confidence: 99%

3D Flexible Frequency Selective Surface with Stable Electromagnetic Transmission Properties

Fan

Pan

Chen

et al. 2022

Adv Materials Technologies

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Frequency selective surfaces (FSS) that can be tightly laminated to complex nondevelopable surfaces have a wide range of applications in many engineering areas. This paper presents a 3D flexible FSS prepared by mechanically guided 3D assembly, capable of being conformally adhered to complex surfaces, while maintaining stable frequency selective properties as well as transmission performance. The stretching strain applied to the prestrained ecoflex substrate can precisely tune and control the buckled 3D metal structures, which leads to the stretchability of the flexible FSS, introduces the increase of the inductance inside the metal cells, and expands the metal gap resulting in a reduction of the capacitance between the unit cells. The mutual correlation of capacitance and inductance ensures in the mechanism that the FSS transmission characteristics will not be significantly affected by the applied strain, as verified by calculations using the equivalent circuit method. Both the results obtained by the experiments and simulations indicate that the resonant frequency of the 3D flexible FSS is 5.7 GHz and the bandwidth at −10 dB is 0.94 GHz, while the resonant frequency shift will not exceed 0.45 Hz, and −10 dB bandwidth change will not exceed 0.32 GHz with applied strain of 17.8% in the ecoflex substrate. At the same time, the 3D flexible FSS maintains stable transmission performance for oblique incidence, with only 0.5 GHz frequency shift at 45° incidence. This stretchable flexible FSS with stable electromagnetic (EM) properties may find potential applications in EM shielding and spatial filtering due to its high flexibility, ready applicability, and cost‐effectiveness.

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“…However, it is challenging in practical realization where most of the fabricated samples can tune or switch from achiral to only one chiral-selective response. [35][36][37] References [38][39][40][41][42][43][44][45][46][47] present detailed theoretical design, fabrication techniques, and tunable mechanisms for chiral metamaterials and metasurfaces. Most of the reported origami/kirigami structures were fabricated using papers or Kapton films, which are difficult to mechanically transform, not robust, and challenging in the fabrication process.…”

Section: Introductionmentioning

confidence: 99%

“…Owing to this unique feature of chiral structures, circularly polarized electromagnetic waves such as left-handed circular polarized (LHCP) or right-handed circular polarized (RHCP) waves can be selectively transmitted, reflected, or absorbed. [34][35][36][37] Deformations from flat to folded shapes (2D to 3D structure) can achieve tunable or reconfigurable chirality. In addition, the reconfigurable characteristics between their opposite chiral states (LHCP and RHCP) can realize Kirigami, with a simple mechanical transformation fashion, offers versatile ways and unconventional approaches for realizing cutting-edge tunable devices.…”

mentioning

confidence: 99%

Rotational Kirigami Tessellation Metasurface for Tunable Chirality

Phon

Jeong

Lim

2022

Adv Materials Technologies

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However, most reported designs are passive, and their functionalities are not reconfigurable after fabrication. Up to now, numerous methodologies have been investigated intensively to realize dynamically tunable metasurfaces, for instance, electrically control (varactor, transistor pin diode), phase change materials, microfluidic, and mechanical. Electrically controlled metasurfaces are commonly used in high switching/tuning speed applications, loading electrical components, such as transistors, varactors, or PIN diodes, on the metasurface structures; [21][22][23] but this technique cannot be applied for higher operating frequencies, such as optical or terahertz regimes, due to manufacturing limitations for electronic components. Various techniques have been proposed, such as phase change materials, to tune or switch electromagnetic functionality, but they still cannot suffer from low tuning or switching ratio. References [24][25][26][27] provided detailed techniques and methods to achieve tunable or reconfigurable metamaterial devices. Non-electrical metasurfaces, i.e., mechanical metasurfaces, have also been proposed, providing tunable or switchable electromagnetic functionality by mechanical deformation or displacement. This approach offers significant advantages in terms of power consumption, simple switching/tuning mechanism, and reconfigurability over continuous state ranges with constant electrical properties; in contrast with electrical components that provide discrete states with nonlinear electrical properties (loss and tuning/switching ratios). [28][29][30] Many such mechanical devices have been proposed from microwave to optical regimes. [31][32][33] Origami is the art of paper folding to create complex or simple structures, whereas kirigami includes the cutting of planar paper. The emerging strategy to integrate origami and kirigami mechanisms for designing mechanical devices has shown great potential to achieve reconfigurability with unique electromagnetic functionality, such as chirality, i.e., asymmetry such that an object cannot superimpose with its mirror image. Owing to this unique feature of chiral structures, circularly polarized electromagnetic waves such as left-handed circular polarized (LHCP) or right-handed circular polarized (RHCP) waves can be selectively transmitted, reflected, or absorbed. [34][35][36][37] Deformations from flat to folded shapes (2D to 3D structure) can achieve tunable or reconfigurable chirality. In addition, the reconfigurable characteristics between their opposite chiral states (LHCP and RHCP) can realize Kirigami, with a simple mechanical transformation fashion, offers versatile ways and unconventional approaches for realizing cutting-edge tunable devices. Here, a rotational kirigami tessellation metasurface with tunable chirality using 2D-to-2D in-plane transformation is designed and experimentally demonstrated. The rotational metasurface is built using flexible filament as a supporting dielectric and silver ink as conductive patterns on the top and bottom layer...

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Mechanical Deformation Induced Circular Dichroism in Propeller‐Shaped Terahertz Metamaterials

Cited by 10 publications

References 54 publications

Kirigami‐Inspired Planar Deformable Metamaterials for Multiple Dynamic Electromagnetic Manipulations

Kirigami‐Inspired Planar Deformable Metamaterials for Multiple Dynamic Electromagnetic Manipulations

3D Flexible Frequency Selective Surface with Stable Electromagnetic Transmission Properties

Rotational Kirigami Tessellation Metasurface for Tunable Chirality

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