Arbitrarily routed mode-division multiplexed photonic circuits for dense integration
Yingjie Liu, Ke Xu, Shuai Wang, Weihong Shen, Hucheng Xie, Yujie Wang,, Shumin Xiao, Yong Yao, Jiangbing Du, Zuyuan He, and Qinghai Song

TL;DR
This paper introduces highly compact, arbitrarily routed mode-division multiplexed photonic circuits using digitized meta-structures, enabling dense integration and high-speed data transmission with minimal chip area.
Contribution
It presents the first MDM circuits based on digitized meta-structures with extremely small footprints and arbitrary routing capabilities.
Findings
3-mode bending radius of 3.9 μm
Crossing footprint of 8x8 μm²
3x100 Gbit/s mode-multiplexed signals with low BER
Abstract
Mode-division multiplexing (MDM) is becoming an enabling technique for large-capacity data communications via encoding the information on orthogonal guiding modes. However, the on-chip routing of a multimode waveguide occupies too large chip area due to the constraints on inter-mode cross talk and mode leakage. Very recently, many efforts have been made to shrink the footprint of individual element like bending and crossing, but the devices still occupy >10x10 um2 footprint for three-mode multiplexed signals and the high-speed signal transmission has not been demonstrated yet. In this work, we demonstrate the first MDM circuits based on digitized meta-structures which have extremely compact footprints. The radius for a three-mode bending is only 3.9 {\mu}m and the footprint of a crossing is only 8x8um2. The 3x100 Gbit/s mode-multiplexed signals are arbitrarily routed through the…
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