Nonlinear silicon photonics analyzed with the moment method

TL;DR

This paper applies the moment method to analyze nonlinear pulse propagation in silicon photonics, deriving analytic expressions and providing fast numerical estimates of pulse evolution considering multiphoton and free-carrier effects.

Contribution

It introduces the first application of the moment method to silicon photonics, deriving analytic formulas for free-carrier effects and comparing dominant dynamics in different waveguides.

Findings

Free-carrier blueshift depends only on pulse peak power.

Group-velocity and free-carrier dispersion dominate in photonic crystal waveguides.

Two-photon and free-carrier absorption dominate in silicon nanowires.

Abstract

We apply the moment method to nonlinear pulse propagation in silicon waveguides in the presence of two-photon absorption, free-carrier dispersion and free-carrier absorption. The evolution equations for pulse energy, temporal position, duration, frequency shift and chirp are obtained. We derive analytic expressions for the free-carrier induced blueshift and acceleration and show that they depend only on the pulse peak power. Importantly, these effects are independent of the temporal duration. The moment equations are then numerically solved to provide fast estimates of pulse evolution trends in silicon photonics waveguides. We find that group-velocity and free-carrier dispersion dominate the pulse dynamics in photonic crystal waveguides. In contrast, two-photon and free-carrier absorption dominate the temporal dynamics in silicon nanowires. To our knowledge, this is the first time the moment method is used to provide a concise picture of multiphoton and free-carrier effects in silicon photonics. The treatment and conclusions apply to any semiconductor waveguide dominated by two-photon absorption.