High-efficiency self-focusing metamaterial grating coupler in silicon nitride with amorphous silicon overlay

Author:

Fraser William,Benedikovic DanielORCID,Korcek Radovan,Milanizadeh Maziyar,Xu Dan-Xia,Schmid Jens H.ORCID,Cheben Pavel,Ye Winnie N.

Abstract

AbstractEfficient fiber-chip coupling interfaces are critically important for integrated photonics. Since surface gratings diffract optical signals vertically out of the chip, these couplers can be placed anywhere in the circuit allowing for wafer-scale testing. While state-of-the-art grating couplers have been developed for silicon-on-insulator (SOI) waveguides, the moderate index contrast of silicon nitride (SiN) presents an outstanding challenge for implementing efficient surface grating couplers on this platform. Due to the reduced grating strength, a longer structure is required to radiate the light from the chip which produces a diffracted field that is too wide to couple into the fiber. In this work, we present a novel grating coupler architecture for silicon nitride photonic integrated circuits that utilizes an amorphous silicon (α-Si) overlay. The high refractive index of the α-Si overlay breaks the coupler’s vertical symmetry which increases the directionality. We implement subwavelength metamaterial apodization to optimize the overlap of the diffracted field with the optical fiber Gaussian mode profile. Furthermore, the phase of the diffracted beam is engineered to focalize the field into an SMF-28 optical fiber placed 55 µm above the surface of the chip. The coupler was designed using rigorous three-dimensional (3D) finite-difference time-domain (FDTD) simulations supported by genetic algorithm optimization. Our grating coupler has a footprint of 26.8 × 32.7 µm2 and operates in the O-band centered at 1.31 μm. It achieves a high directionality of 85% and a field overlap of 90% with a target fiber mode size of 9.2 µm at the focal plane. Our simulations predict a peak coupling efficiency of − 1.3 dB with a 1-dB bandwidth of 31 nm. The α-Si/SiN grating architecture presented in this work enables the development of compact and efficient optical interfaces for SiN integrated photonics circuits with applications including optical communications, sensing, and quantum photonics.

Funder

Carleton University, Electronics, Ottawa, Canada

University of Zilina, Dept. Multimedia and Information-Communication Technology, Zilina, Slovakia

University of Zilina, Zilina, Slovakia

National Research Council Canada, Ottawa, Canada

National Research Council Canada, Institute for Microstructural Sciences, Ottawa, Ontario, Canada

Carleton University, Ottawa, Canada

Gouvernement du Canada | National Research Council Canada

Gouvernement du Canada | Natural Sciences and Engineering Research Council of Canada

Publisher

Springer Science and Business Media LLC

Cited by 2 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

1. Advances in Low-Loss Fiber-Chip Couplers for Silicon Nitride Photonic Integrated Circuits;2024 IEEE 24th International Conference on Nanotechnology (NANO);2024-07-08

2. Design of Efficient Single-Etch Grating Couplers for Silicon Nitride Photonics at 1550 NM;2024 Photonics North (PN);2024-05-28

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