Silicon Nitride C-Band Grating Coupler with Reduced Waveguide Back-Reflection Using Adaptively Corrected Elliptical Grates

TL;DR

This paper demonstrates a silicon nitride C-band grating coupler with significantly reduced back reflection and minimized insertion loss by using adaptively corrected elliptical grates, improving coupling efficiency in photonic circuits.

Contribution

It introduces a novel design combining interrupted gratings with elliptical reshaping to suppress back reflection and reduce insertion loss in silicon nitride grating couplers.

Findings

Back reflection reduced by ~10 dB.

Insertion loss penalty decreased from 2.4 dB to 1 dB.

Effective suppression of back reflection while maintaining high coupling efficiency.

Abstract

We present experimental results for a fully etched C-band grating coupler with reduced back reflection fabricated in an 800 nm silicon nitride platform. Back-reflections are reduced by symmetrically interrupting the first few grates around the center axis of the propagating light. The span of the etched grates is gradually increased until they cover the full width. By interrupting the grates, light is reflected back obliquely, which leads to the excitation of higher-order modes that are scattered out of the structure. While this approach has been previously shown in silicon, it comes with a significant penalty in coupling efficiency of around 2.4 dB of extra loss in the layer stack investigated here. In this work, we present the design and measurement results of a grating coupler in which waveguide-to-waveguide back-reflections are suppressed by ~10 dB with this technique, while at the same time mitigating excess insertion losses by reshaping the grates as ellipses of varying eccentricity. This helps to compensate the phase front error induced by the interruption of the grates. This correction does not affect the level by which the back-reflection is suppressed, but reduces the insertion loss penalty from 2.4 dB to 1 dB.