Ultrafast pulse propagation time-domain dynamics in dispersive one-dimensional photonic waveguides

TL;DR

This paper introduces a design methodology for ultrafast pulse propagation in dispersive integrated waveguides, achieving significant improvements in peak power and pulse duration control on a silicon platform.

Contribution

It presents a novel design approach and fabrication of optimized 1D grating waveguides for ultrafast pulses, validated by a digital FIR model for enhanced time-domain performance.

Findings

2.78-fold increase in peak power

24% reduction in pulse broadening

Improved temporal resolution with minimal sacrifice

Abstract

Ultrafast pulses, particularly those with durations under 100 femtoseconds, are crucial in achieving unprecedented precision and control in light-matter interactions. However, conventional on-chip photonic platforms are not inherently designed for ultrafast time-domain operations, posing a significant challenge in achieving essential parameters such as high peak power and high temporal resolution. This challenge is particularly pronounced when propagating through dispersive integrated waveguides, unlike classical applications where dispersion is typically near-zero or linear. In addressing this challenge, we present a design methodology for ultrafast pulse propagation in dispersive integrated waveguides, specifically focused on enhancing the time-domain characteristics of one-dimensional grating waveguides (1DGWs). The proposed methodology aims to determine the optimal structural parameters for achieving maximum peak power, enhanced temporal resolution, and extended pulse storage duration during ultrafast pulse propagation. To validate this approach, we design and fabricate two specialized 1DGWs on a silicon-on-insulator (SOI) platform. A digital finite impulse response (FIR) model, trained with both transmission and phase measurement data, is employed to obtain ultrafast time-domain characteristics, enabling easy extraction of these results. Our approach achieves a 2.78-fold increase in peak power and reduces pulse broadening by 24%, resulting in a smaller sacrifice in temporal resolution. These results can possibly pave the way for advanced light-matter interactions within dispersive integrated waveguides.