Photonic switching devices based on semiconductor nanostructures

TL;DR

This review explores semiconductor nanostructure-based photonic switches, emphasizing their potential for high-speed, low-power optical networks through enhanced nonlinearity and cavity effects.

Contribution

It introduces a theoretical framework for analyzing optical nonlinearity in QD/cavity switches and reviews current experimental progress and emerging techniques.

Findings

Field enhancement significantly improves power-density and speed.

QD/cavity switches reduce power consumption due to their nanoscale properties.

Cavity nonlinear effects enable advanced functionalities like wavelength tuning.

Abstract

Focusing and guiding light into semiconductor nanostructures can deliver revolutionary concepts for photonic devices, which offer a practical pathway towards next-generation power-efficient optical networks. In this review, we consider the prospects for photonic switches using semiconductor quantum dots (QDs) and photonic cavities which possess unique properties based on their low dimensionality. The optical nonlinearity of such photonic switches is theoretically analyzed by introducing the concept of a field enhancement factor. This approach reveals drastic improvement in both power-density and speed, which is able to overcome the limitations that have beset conventional photonic switches for decades. In addition, the overall power consumption is reduced due to the atom-like nature of QDs as well as the nano-scale footprint of photonic cavities. Based on this theoretical perspective, the current state-of-the-art of QD/cavity switches is reviewed in terms of various optical nonlinearity phenomena which have been utilized to demonstrate photonic switching. Emerging techniques, enabled by cavity nonlinear effects such as wavelength tuning, Purcell-factor tuning and plasmonic effects are also discussed.