Angular‐Adaptive Spin‐Locked Retroreflector Based on Reconfigurable Magnetic Metagrating

Li, Min; Jing, Liqiao; Lin, Xiao; Xu, Su; Shen, Lian; Zheng, Bin; Wang, Zuojia; Chen, Hongsheng

doi:10.1002/adom.201900151

Cited by 26 publications

(18 citation statements)

References 49 publications

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“…In addition to the specific functionalities, strongly anisotropic GSP meta-atoms have been utilized to achieve linear-polarization-selective [23][24][25] or spin-selective [25,26] distinct functionalities, where each polarization state is subjected to a different wavefront transformation. However, the aforementioned linear-polarization-selective GSPMs lack the capability of polarization conversion, which is detrimental for the signal-to-noise ratio due to the overlap between the signal beam and the background.…”

Section: Introductionmentioning

confidence: 99%

Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting

Ding¹,

Chen²,

Bozhevolnyi³

2020

Photon. Res.

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Gap-surface plasmon (GSP) metasurfaces have attracted progressively increasing attention due to their planar configurations, ease of fabrication, and unprecedented capabilities in manipulating the reflected fields that enable integrating diverse bulk-optic-based optical components into a single ultrathin flat element. In this work, we design and experimentally demonstrate multifunctional metalenses that perform simultaneous linear-polarization conversion, focusing, and beam splitting, thereby reproducing the combined functionalities of conventional halfwave plates, parabolic reflectors, and beam splitters. The fabricated single-focal metalens incorporates properly configured distinct half-wave-plate-like GSP meta-atoms and exhibits good performance under linearly polarized incidence in terms of orthogonal linear-polarization conversion (>75%) and focusing (overall efficiency > 22%) in the wavelength spectrum ranging from 800 to 950 nm. To further extend the combined functionalities, we demonstrate a dual-focal metalens that splits and focuses a linearly polarized incident beam into two focal spots while maintaining the capability of orthogonal linear-polarization conversion. Furthermore, the power distribution between two split beams can readily be controlled by judiciously positioning the incident beam. The demonstrated multifunctional GSP-based metalenses mimic the combined functionalities of a sequence of discrete bulk optical components, thereby eliminating the need for their mutual alignment and opening new perspectives in the development of ultracompact and integrated photonic devices.

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Section: Introductionmentioning

confidence: 99%

Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting

Ding¹,

Chen²,

Bozhevolnyi³

2020

Photon. Res.

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“…In the following, we demonstrated another more advanced function, called a reverser, by using our Janus metasurface, which enables to reverse predefined in-plane components of momentum in Employing metasurface for such a task has been an intriguing issue most recently [46]- [50] , especially for the adaptive retroreflector, which is only demonstrated by mechanically altering the geometry of reconfigurable C-shaped resonators [48] or switchable metagrating [49] .…”

Section: Wide-angle Large-capacity Reversermentioning

confidence: 99%

Spin-encoded Wavelength-space Multitasking Janus Metasurfaces 

Xu¹,

Wang²,

Wang³

et al. 2020

Preprint

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The fruitful progress toward light manipulation in reflective (R) or transmissive (T) geometry (half-space) has facilitated strong aspiration to achieving full-space electromagnetic wave control in both R and T channels. Although it promises large-capacity and integrated functionality, yet imposes prohibitive difficulty and big challenging for extreme wave control (direction of arrival in full space) via an ultrathin flat device. As of today, very limited demonstrations were reported for single-band and linear-polarization operation, significantly limiting the exploitable degree of freedoms (DoFs) for real-world applications. Herein, we report for the first time a triple-layer wavelength-space multitasking scheme for wide-angle and large-capacity detection. Two anisotropic sub-meta-atoms are engineered with high quality factor and simultaneous in-plane and out-of-plane symmetry breaking, facilitating four R and two T spin-conversion channels with high efficiency and insulation. The chirality-assisted Fano effect gives rise to the wide-angle operation and boosted channels. Above features and released DoF would be extraordinary beneficial for large-capability and angle-engineered advanced device. Two proof-of-concept metadevices, i.e., large-scanning kaleidoscopic-beam generator and a wide-angle large-capacity reverser for multi-target tracking, are devised to verify the significance. Numerical and experimental results have approved predesigned advanced functions at six channels with measured efficiency over 75%. Our findings in multi-DoF multitasking of metasurfaces could stimulate great interest in radar applications with versatile beam generation and multi-channel integration.

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“…Moreover, the dielectric metasurface can be processed at low cost using standard nanofabrication approaches. To date, various metasurfaces with extraordinary functionalities have been demonstrated, such as metalenses [4,[10][11][12][13], metasurface gratings [14,15], orbital angular momentum (OAM) generators [16,17], retroreflectors [18][19][20], metaholograms [21][22][23], structured light generators [24,25], and nonlinear optics [26], covering a wide spectrum from ultraviolet to microwave wavelengths. Recently, metasurfaces have been employed in biosensing applications [27].…”

Section: Introductionmentioning

confidence: 99%

Broadband Achromatic Metasurfaces for Longwave Infrared Applications

Song

Shan

et al. 2021

Nanomaterials

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Longwave infrared (LWIR) optics are essential for several technologies, such as thermal imaging and wireless communication, but their development is hindered by their bulk and high fabrication costs. Metasurfaces have recently emerged as powerful platforms for LWIR integrated optics; however, conventional metasurfaces are highly chromatic, which adversely affects their performance in broadband applications. In this work, the chromatic dispersion properties of metasurfaces are analyzed via ray tracing, and a general method for correcting chromatic aberrations of metasurfaces is presented. By combining the dynamic and geometric phases, the desired group delay and phase profiles are imparted to the metasurfaces simultaneously, resulting in good achromatic performance. Two broadband achromatic metasurfaces based on all-germanium platforms are demonstrated in the LWIR : a broadband achromatic metalens with a numerical aperture of 0.32, an average intensity efficiency of 31%, and a Strehl ratio above 0.8 from 9.6 μm to 11.6 μm, and a broadband achromatic metasurface grating with a constant deflection angle of 30° from 9.6 μm to 11.6 μm. Compared with state-of-the-art chromatic-aberration-restricted LWIR metasurfaces, this work represents a substantial advance and brings the field a step closer to practical applications.

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Angular‐Adaptive Spin‐Locked Retroreflector Based on Reconfigurable Magnetic Metagrating

Cited by 26 publications

References 49 publications

Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting

Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting

Spin-encoded Wavelength-space Multitasking Janus Metasurfaces

Broadband Achromatic Metasurfaces for Longwave Infrared Applications

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Angular‐Adaptive Spin‐Locked Retroreflector Based on Reconfigurable Magnetic Metagrating

Cited by 26 publications

References 49 publications

Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting

Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting

Spin-encoded Wavelength-space Multitasking Janus Metasurfaces&nbsp;

Broadband Achromatic Metasurfaces for Longwave Infrared Applications

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Product

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Spin-encoded Wavelength-space Multitasking Janus Metasurfaces