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Paper detail

Nondestructive on-chip detection of optical orbital angular momentum through a single plasmonic nanohole

Optical orbital angular momentum (OAM) provides an additional dimension for photons to carry information in high-capacity optical communication. Although the practical needs have intrigued the generations of miniaturized devices to manipulate the OAM modes in various integrated platforms, the on-chip OAM detection is still challenging to match the newly-developed compact OAM emitter and OAM transmission fiber. Here, we demonstrate an ultra-compact device, i.e., a single plasmonic nanohole, to efficiently measure an optical beam's OAM state in a nondestructive way. The device size is reduced down to a few hundreds of nanometers, which can be easily fabricated and installed in the current OAM devices. It is a flexible and robust way for in-situ OAM monitoring and detection in optical fiber networks and long-distance optical communication systems. With proper optimization of the nanohole parameters, this approach could be further extended to discriminate the OAM information multiplexed in multiple wavelengths and polarizations.

preprint2016arXivOpen access
Dunzhao WeiYongmei WangDongmei LiuYunzhi ZhuWeihao ZhongXinyuan FangYong ZhangMin Xiao
physics.optics
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Dunzhao WeiYongmei WangDongmei LiuYunzhi ZhuWeihao ZhongXinyuan FangYong ZhangMin Xiao

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