Direction-dependent Optical Modes in Nanoscale Silicon Waveguides

TL;DR

This paper reveals that in nanoscale silicon waveguides, forward and reflected optical modes have distinct near-field profiles, enabling potential new methods for filtering and controlling light propagation in integrated photonic circuits.

Contribution

It demonstrates that high-index-contrast silicon waveguides produce distinguishable near-field profiles for counter-propagating light, a novel insight for photonic device design.

Findings

Distinct near-field profiles for forward and reflected light

Potential for new optical filtering elements

Mapping of mode profiles using TraNSOM

Abstract

On-chip photonic networks have the potential to transmit and route information more efficiently than electronic circuits. Recently, a number of silicon-based optical devices including modulators, buffers, and wavelength converts have been reported. However, a number of technical challenges need to be overcome before these devices can be combined into network-level architectures. In particular, due to the high refractive index contrast between the core and cladding of semiconductor waveguides, nanoscale defects along the waveguide often scatter light into the backward-propagating mode. These reflections could result in unwanted feedback to optical sources or crosstalk in bidirectional interconnects such as those employed in fiber-optic networks. It is often assumed that these reflected waves spatially overlap the forward-propagating waves making it difficult to implement optical circulators or isolators which separate or attenuate light based on its propagation direction. Here, we individually identify and map the near-field mode profiles of forward-propagating and reflected light in a single-mode silicon waveguide using Transmission-based near-field scanning optical microscopy (TraNSOM). We show that unlike fiber-optic waveguides, the high-index-contrast and nanoscale dimensions of semiconductor waveguides create counter propagating waves with distinct spatial near-field profiles. These near-field differences are a previously-unobserved consequence of nanoscale light confinement and could provide a basis for novel elements to filter forward-propagating from reflected light.