Abstract
The metasurface-based superoscillatory lens has been demonstrated to be effective in finely tailoring the wavefront of light to generate focal spots beyond the diffraction limit in the far-field that is capable of improving the resolution of the imaging system. In this paper, an ultra-thin (0.055 λ0) metasurface-based superoscillatory lens (SOL) that can generate a sub-diffraction optical needle with a long focal depth is proposed, which is constructed by ultra-thin chiral unit cells containing two metal split-ring resonators (SRR) with a 90° twisted angle difference cladded on both sides of a 1.5 mm-thick dielectric substrate, with a high linear cross-polarized transmission coefficient around 0.9 and full phase control capability at 11 GHz. Full-wave simulation shows that SOL generates a sub-diffraction optical needle within 10.5–11.5 GHz. At the center frequency, the focal depth is 281 mm (10.3 λ0) within 105–386 mm, the full width at half maximum (FWHM) is 18.5 mm (0.68 λ0), about 0.7 times the diffraction limit, generally consistent with the theoretical result. The proposed ultra-thin chiral metasurface-based SOL holds great potential in integrating into practical imaging applications for its simple fabrication, high efficiency, and low-profile advantages.
Highlights
Electromagnetic (EM) wave manipulation is an appealing research field for it is one of the key points to push forward the development of science and engineering
We propose a high transmission ultra-thin chiral unit cell consisting of two identical metal split-ring resonators (SRR) with a 90° twisted angle difference cladded on a 1.5 mm-thick (0.055 λ0) dielectric substrate
The theoretical calculation and full-wave simulation results at 11 GHz of the designed lens with 200 mm focal length and superoscillatory lens (SOL) are shown in Figure 6, where the full-wave simulation is solved by Lumerical FDTD
Summary
Electromagnetic (EM) wave manipulation is an appealing research field for it is one of the key points to push forward the development of science and engineering. A Metasurface is a novel artificial thin two-dimensional artificial material consisting of subwavelength elements, which provides a powerful platform to manipulate the EM wave with high degrees of freedom (Holloway et al, 2012; Yu et al, 2013; Yu and Capasso, 2014). Tailoring the wavefront is one of the typical applications of a metasurface (Yu et al, 2011; Yu et al, 2013), which is realized by arraying subwavelength elements with different phase and magnitude responses into a special layout.
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