Litcius/Paper detail

Efficient light coupling between conventional silicon photonic waveguides and quantum valley-Hall topological interfaces

Lei Chen, Mingyang Zhao, Han Ye, Zhi Hong Hang, Ying Li, Zizheng Cao

2022Optics Express15 citationsDOIOpen Access PDF

Abstract

Robust and efficient light coupling into and out of quantum valley-Hall (QVH) topological interfaces within near-infrared frequencies is demanded in order to be integrated into practical two-dimensional (2D) optical chips. Here, we numerically demonstrate efficient light coupling between a QVH interface and a pair of input/output silicon photonic waveguides in the presence of photonic crystal line defects. When the topological QVH interface is directly end-butt coupled to the silicon waveguides, the input-to-output transmission efficiency is lower than 50% and the exterior boundaries associated with a QVH interface also cause inevitable back-reflections and high-order scatterings, further reducing the transmission efficiency. The transmission efficiency is substantially increased to 95.8% (94.3%) when photonic crystal line defects are introduced between the bridge (zigzag) QVH interface and the waveguides. The buffering line defect mode, with an effective group refractive index between the interface state and the waveguide mode will ease their mode profile conversion. The design we present here brings no fabrication complexity and may be used as a guide for future implementation of on-chip 2D topological photonics.

Topics & Concepts

Photonic crystalOptoelectronicsCoupling (piping)OpticsPhotonicsTopology (electrical circuits)Coupled mode theoryWaveguideInterface (matter)Materials scienceSiliconSilicon photonicsTransmission (telecommunications)Refractive indexPhotonic integrated circuitSlow lightQuantum opticsFabricationPhysicsLine (geometry)QuantumQuantum computerMode couplingYablonoviteTransmission coefficientTopological Materials and PhenomenaPhotonic Crystals and ApplicationsGraphene research and applications