Enhanced Optical Activity with Zero Circular Dichroism in a Dielectric Chiral Metasurface

Zhang, Zhiyu; Wang, Haoyu; Zhao, Kun; Zang, Haofeng; Liu, Liangliang; Wen, Liu; Wang, Pei; Lü, Yonghua

doi:10.1002/adom.202300853

Cited by 2 publications

(1 citation statement)

References 49 publications

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“…Exploring spinpolarized (circularly polarized) waves has garnered significant attention in areas like chiral optics and spin-controlled * Authors to whom any correspondence should be addressed. nanophotonic [12][13][14][15]. Using spin angular momentum facilitates the engineering of spin-dependent nanoscale interactions between light and matter.…”

Section: Introductionmentioning

confidence: 99%

Strong spinning thermal radiation enabled by germanium-based chiral dielectric metasurface

Guo,

Wu,

et al. 2024

J. Opt.

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Spinning thermal radiation refers to the phenomenon of selective emission of circularly polarized waves from chiral structures with polarization dependence or symmetry breaking. This phenomenon finds diverse applications in fields such as radiation detection and chiral sensing. In this study, we introduce a dielectric metasurface composed of a periodic arrangement of Germanium (Ge) elliptical disks, which can exhibit circular dichroism (CD) with a maximum value of approximately 0.93 at the optimal structural parameters. The physical mechanism of the strong CD is analyzed through the polarization conversion and distributions of the electric field. Moreover, the influence of structural parameters on the spinning thermal radiation is also analyzed. It is found that the CD is closely related to the height and period of the Ge-based chiral dielectric metasurface rather than the rotation angle. This work not only provides valuable insights into the design and optimization of spinning thermal radiation using metasurfaces, but also holds promise for its engineering applications in the field of thermal detection.

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Section: Introductionmentioning

confidence: 99%

Strong spinning thermal radiation enabled by germanium-based chiral dielectric metasurface

Guo,

Wu,

et al. 2024

J. Opt.

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Multi‐Scale Design of Metal–Organic Framework Metamaterials for Broad‐Band Microwave Absorption

Qu,

Xu,

Liu

et al. 2024

Adv Funct Materials

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The development of nanocomposite microwave absorbers is a critical strategy for tackling electromagnetic pollution. However, challenges persist regarding material stability and achieving broadband absorption. Herein, a novel multi−scale design approach for metamaterial absorbers is proposed. First, a series of bimetallic (cobalt and copper) semiconductive metal–organic framework (SC−MOF) crystals with atomically resolved structures are successfully prepared to serve as building blocks for metamaterials. By simply adjusting the concentration ratio of the two ions, the controllable preparation of crystal morphology can be achieved. This enables to precisely tune the absorption peak and bandwidth range of the SC−MOF, resulting in excellent EMW absorption performance (effective absorption bandwidth: 6.16 GHz, minimum reflection loss: −61 dB). Based on this, printable inks are further constructed by encapsulating the SC−MOF in polydimethylsiloxane and 3D‐printed multi−layered metamaterial absorbers based on woodpile porous architecture. The metamaterial absorber demonstrates a near‐perfect absorption in the microwave spectrum (with a bandwidth of 11.33 GHz), closely matching theoretical simulations. This multi−scale design approach, combining precise MOF materials construction with topological structure design, offers new insights for the development of broadband microwave absorbers.

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Enhanced Optical Activity with Zero Circular Dichroism in a Dielectric Chiral Metasurface

Cited by 2 publications

References 49 publications

Strong spinning thermal radiation enabled by germanium-based chiral dielectric metasurface

Strong spinning thermal radiation enabled by germanium-based chiral dielectric metasurface

Multi‐Scale Design of Metal–Organic Framework Metamaterials for Broad‐Band Microwave Absorption

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