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Paper detail

Approaching the Fundamental Limit of Orbital Angular Momentum Multiplexing Through a Hologram Metasurface

Establishing and approaching the fundamental limit of orbital angular momentum (OAM) multiplexing are necessary and increasingly urgent for current multiple-input multiple-output research. In this work, we elaborate the fundamental limit in terms of independent scattering channels (or degrees of freedom of scattered fields) through angular-spectral analysis, in conjunction with a rigorous Green function method. The scattering channel limit is universal for arbitrary spatial mode multiplexing, which is launched by a planar electromagnetic device, such as antenna, metasurface, etc, with a predefined physical size. As a proof of concept, we demonstrate both theoretically and experimentally the limit by a metasurface hologram that transforms orthogonal OAM modes to plane-wave modes scattered at critically separated angular-spectral regions. Particularly, a minimax optimization algorithm is applied to suppress angular spectrum aliasing, achieving good performances in both full-wave simulation and experimental measurement at microwave frequencies. This work offers a theoretical upper bound and corresponding approach route for engineering designs of OAM multiplexing.

preprint2022arXivOpen access
Shuai S. A. YuanJie WuMenglin L. N. ChenZhihao LanLiang ZhangSheng SunZhixiang HuangXiaoming ChenShilie ZhengLi Jun JiangXianmin ZhangWei E. I. Sha
physics.app-phphysics.optics
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Shuai S. A. YuanJie WuMenglin L. N. ChenZhihao LanLiang ZhangSheng SunZhixiang HuangXiaoming ChenShilie ZhengLi Jun JiangXianmin ZhangWei E. I. Sha

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