Abstract
AbstractIn this paper, a novel method is proposed to achieve two distinct information channels by simultaneously manipulating both the transmitted cross- and co-polarized components of a 1-bit coding metasurface under linearly polarized incidence. Compared to previously demonstrated incidence-switchable or position multiplexed holograms, our proposed coding meta-hologram can simultaneously project two independent holographic images without inevitable change of the incidence state and can at the same time also avoid crosstalk between different channels. Moreover, the orientation of the double-layered split ring (SR) apertures is specially designed to be 45° or 135° to achieve identical multiplexed functionality for bothx-polarized andy-polarized incidences. The proof-of-concept experimental demonstrations present total transmittance efficiency above 30% for the dual linearly polarized incidences at 15 GHz, and good imaging performances with 53.98%/48.18% imaging efficiency, 1.55%/1.46% RMSE, and 29.9/28.72 peak signal-to-noise ratio for the cross-/co-polarized channels undery-polarized incidence, and 47.27%/45.75% imaging efficiency, 1.55%/1.43% RMSE, and 18.74/25.93 peak signal-to-noise ratio underx-polarized incidence, demonstrating great potential of the proposed multiplexed coding meta-hologram in practical applications such as data storage and information processing.
Highlights
Holography is one of the most promising imaging techniques to record and reconstruct full wave information of objects [1]
Compared to previously demonstrated incidence-switchable or position multiplexed holograms, our proposed coding meta-hologram can simultaneously project two independent holographic images without inevitable change of the incidence state and can at the same time avoid crosstalk between different channels
Since the imaging plane is in the radiative near-field region, the longitudinal polarized (Ez) component exists, as discussed in detail in Supplementary material S2
Summary
Holography is one of the most promising imaging techniques to record and reconstruct full wave information of objects [1]. Metasurfaces, composed of arrays of artificially designed planar subwavelength-scaled scatterers, are two-dimensional analogues of metamaterials [5,6,7,8,9,10]. Due to their extraordinary capability in tailoring wavefronts, numerous applications of metasurfaces have been proposed, such as anomalous reflectors/refractors [11, 12], metalenses [13, 14], orbital angular momentum (OAM) generators [15, 16], metagratings [17, 18] and multifunctional devices [19, 20], to name a few. Metasurface can provide unprecedented spatial resolution, low noise and high precision of the reconstructed images, and establish the feasibility of multiplexed hologram without introducing distortion in the reconstruction [20, 34,35,36,37,38,39,40,41]
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