Your search keyword '"Xu Mingfeng"' showing total 5 results

1. High-efficiency and broadband asymmetric spin–orbit interaction based on high-order composite phase modulation

Author

Ou Yuzhong, Chen Yan, Zhang Fei, Pu Mingbo, Jiang Mengna, Xu Mingfeng, Guo Yinghui, Feng Chaolong, Gao Ping, and Luo Xiangang

Subjects

asymmetric spin-orbit interaction, generalized geometric phase, all-metallic structure, metasurface, Physics, QC1-999

Abstract

Asymmetric spin–orbit interaction (ASOI) breaks the limitations in conjugate symmetry of traditional geometric phase metasurfaces, bringing new opportunities for various applications such as spin-decoupled holography, imaging, and complex light field manipulation. Since anisotropy is a requirement for spin–orbit interactions, existing ASOI mainly relies on meta-atom with C1 and C2 symmetries, which usually suffer from an efficiency decrease caused by the propagation phase control through the structural size. Here, we demonstrate for the first time that ASOI can be realized in meta-atoms with rotational symmetry ≥3 by combining the generalized geometric phase with the propagation phase. Utilizing an all-metallic configuration, the average diffraction efficiency of the spin-decoupled beam deflector based on C3 meta-atoms reaches ∼84 % in the wavelength range of 9.3–10.6 μm, which is much higher than that of the commonly used C2 meta-atoms with the same period and height. This is because the anisotropy of the C3 metasurface originates from the lattice coupling effect, which is relatively insensitive to the propagation phase control through the meta-atom size. A spin-decoupled beam deflector and hologram meta-device were experimentally demonstrated and performed well over a broadband wavelength range. This work opens a new route for ASOI, which is significant for realizing high-efficiency and broadband spin-decoupled meta-devices.

Published

2024

2. High-resolution non-line-of-sight imaging based on liquid crystal planar optical elements

Author

Zhao Zhibin, Zhang Qi, Li Xiaoyin, Guo Yinghui, Pu Mingbo, Zhang Fei, Guo Hengshuo, Wang Zewei, Fan Yulong, Xu Mingfeng, and Luo Xiangang

Subjects

metasurface, liquid crystal planar optical element, non-line-of-sight imaging, Physics, QC1-999

Abstract

Non-line-of-sight (NLOS) imaging aims at recovering hidden objects located beyond the traditional line of sight, with potential applications in areas such as security monitoring, search and rescue, and autonomous driving. Conventionally, NLOS imaging requires raster scanning of laser pulses and collecting the reflected photons from a relay wall. High-time-resolution detectors obtain the flight time of photons undergoing multiple scattering for image reconstruction. Expanding the scanning area while maintaining the sampling rate is an effective method to enhance the resolution of NLOS imaging, where an angle magnification system is commonly adopted. Compared to traditional optical components, planar optical elements such as liquid crystal, offer the advantages of high efficiency, lightweight, low cost, and ease of processing. By introducing liquid crystal with angle magnification capabilities into the NLOS imaging system, we successfully designed a large field-of-view high-resolution system for a wide scanning area and high-quality image reconstruction. Furthermore, in order to reduce the long data acquisition time, a sparse scanning method capitalizing on the correlation between measurement data to reduce the number of sampling points is thus proposed. Both the simulation and experiment results demonstrate a >20 % reduction in data acquisition time while maintaining the exact resolution.

Published

2024

3. Optical Information Encryption Based on Secret Sharing Liquid Crystal Elements with Spatial Dislocation.

Author

Xu, Xin, Qiao, Siyuan, Guo, Yinghui, Zhang, Qi, Fu, Guoquan, Pu, Mingbo, Fan, Yulong, Li, Xiaoyin, Zhang, Fei, Xu, Mingfeng, Duan, Fei, and Luo, Xiangang

Subjects

LIQUID crystal states, INFORMATION technology security, LIQUID crystals, GEOMETRIC quantum phases, OPTICS

Abstract

Optical encryption is an increasingly significant technique in the realm of information security. In the recent decade, there has been considerable interest in using planar optics elements for information encryption. However, information leakage possibly occurs due to limited encrytion channels available for single‐layer devices. To circumvent this problem, a novel encryption method is put forward using secret sharing cascaded liquid crystal (LC) elements with spatial dislocation, which can produce near‐field patterns and far‐field holographic images under different illumination conditions. Specifically, Malus's Law and its inherent one‐to‐four mapping of rotational degeneracy, along with the Pancharatnam‐Berry (PB) phase introduced by LC molecules, to achieve multi‐channel encryption are utilized. Therefore, each cascaded LC unit can manipulate the amplitude and phase imparted to output light independently, thus only by obtaining both LC devices can decryption be realized. To further enhance the encryption security, the author purposely divide each LC device into multiple regions and find that the encrypted patterns can only be recovered when the two LC elements align precisely with a specific dislocation. These experimental measurements agree well with the design, thus demonstrating the strong encryption capability and broad application prospects of the design approach in the field of optical encryption with high cost‐effectiveness. [ABSTRACT FROM AUTHOR]

Published

2024

4. Dual‐Layer Metasurface Enhanced Capacity of Polarization Multiplexing.

Author

Zhang, Runzhe, Guo, Yinghui, Zhang, Fei, Pu, Mingbo, Fan, Yulong, Zhang, Qi, Li, Xiaoyin, Xu, Mingfeng, Xu, Junwen, and Luo, Xiangang

Subjects

SINGLE-degree-of-freedom systems, OPTICAL devices, DEGREES of freedom, NUMERICAL calculations, MULTIPLEXING

Abstract

Polarization is the nature of optics. Exploiting metasurface's polarizations can enhance the multiplexing capacity but face a limited number of channels. For example, a single‐layer metasurface can offer three independent channels with six degrees of freedom (DoFs) including the amplitude and phase of Ex, Exy(yx), and Ey of the Jones matrix. In this work, it is theoretically demonstrated that the degrees of freedom of dual‐layer metasurfaces can reach eight, overcoming the polarization multiplexing constraints of single‐layer metasurfaces and that the cross‐talk can be largely reduced as compared with single‐layer metasurfaces when the channel number is larger than three. Numerical calculations manifest a decrease of 100%, 63%, and 50% for the cross‐talk of channels 4, 5, and 6, respectively. As a proof‐of‐concept demonstration of high‐capacity polarization multiplexing, an arbitrary‐polarization‐controlled 5‐channel dual‐layer metasurface exhibiting five nanoprintings and five holographic images with reduced cross‐talk under different incident and output polarizations is successfully designed. Thus, the research highlighting the high‐multiplexing‐capacity of dual‐layer metasurfaces can significantly advance multifunctional optical devices with high efficiency, simple integration, and ease of manipulation. [ABSTRACT FROM AUTHOR]

Published

2024

5. Generation of High‐Purity Full Poincaré Beam Arrays via Metasurface Integrated Degenerate Cavity.

Author

Ma, Siyuan, Xu, Mingfeng, Pu, Mingbo, Zheng, Yuhan, Zeng, Qingji, Luo, Xin, Zhang, Fei, Guo, Yinghui, Li, Xiong, Ma, Xiaoliang, and Luo, Xiangang

Subjects

*ANGULAR momentum (Mechanics), *CIRCULAR polarization, *OPTICAL communications, *INTERSTELLAR communication, *VECTOR beams, *BESSEL beams, *GENERATION X

Abstract

Recently, full Poincaré beams (FPBs) with spatially variant polarization states spanning the entire surface of the Poincaré sphere have attracted considerable interests. Expanding the FPBs into an array way has the promising applications from multiparticle manipulation to optical communication. However, how to efficiently generate a high‐purity FPB array with intracavity method remains elusive. Here, a metasurface‐integrated degenerate cavity laser is proposed for efficient generation of 10 × 10 FPB array, where a pair of metasurfaces are adopted to independently modulate the circular polarization state while compensating the mode discrepancies within the cavity. Such a design strategy enables a self‐reproducing intracavity optical field, concurrently ensuring the stabilization of intracavity oscillation. It is numerically demonstrated that the purity of orbital angular momentum (OAM) in the first‐order FPB array can approach to 92.89%, with a root‐mean‐square error (RMSE) of polarization ellipse parameters below 8.17%. This work provides a compact and efficient design platform for the generation of a variety of vector beam arrays and may find promising applications in free space communication and multiple particle manipulation. [ABSTRACT FROM AUTHOR]

Published

2024