Jia Ridong, Tan Yi Ji, Navaratna Nikhil, Kumar Abhishek, Singh Ranjan
Division of Physics and Applied Physics, School of Physical and Mathematical Sciences, Nanyang Technological University, Singapore, 637371, Singapore.
Centre for Disruptive Photonic Technologies, Nanyang Technological University, Singapore, 639798, Singapore.
Adv Mater. 2025 Feb;37(6):e2415083. doi: 10.1002/adma.202415083. Epub 2024 Dec 17.
Waveguide interconnect coupling control is essential for enhancing the chip density of photonic integrated circuits to incorporate a growing number of components. However, a critical engineering challenge is to achieve both strong waveguide isolation and efficient long-range coupling on a single chip. Here, a novel photonic supercoupling phenomenon is demonstrated for waveguide coupling over separation distances from a quarter to five wavelengths (λ), leveraging the tunable mode tails and the vortex energy flow in topological valley Hall system. A supercoupled integrated chip is developed, realizing a 91% coupling ratio and a -30 dB isolation over 2.8λ waveguide separations simultaneously. Supercoupled devices are further showcased including a waveguide-cavity system with 3.2λ excitation distance, and a waveguide directional supercoupler with a compact coupling area of nearly λ/4, which outperform conventional devices. Supercoupling provides new degrees of freedom for optimizing coupling and isolation between photonic integrated components, facilitating new applications in on-chip sensing, lasing, and telecommunications.
波导互连耦合控制对于提高光子集成电路的芯片密度以纳入越来越多的组件至关重要。然而,一个关键的工程挑战是在单个芯片上实现强波导隔离和高效的长程耦合。在此,利用拓扑谷霍尔系统中可调谐的模式尾和涡旋能量流,展示了一种新颖的光子超耦合现象,用于在从四分之一波长到五个波长(λ)的分离距离上进行波导耦合。开发了一种超耦合集成芯片,在2.8λ的波导分离距离上同时实现了91%的耦合比和-30 dB的隔离度。进一步展示了超耦合器件,包括具有3.2λ激发距离的波导-腔系统和具有近λ/4紧凑耦合面积的波导定向超耦合器,其性能优于传统器件。超耦合为优化光子集成组件之间的耦合和隔离提供了新的自由度,促进了片上传感、激光和电信等新应用。
