Nonlinear carrier dynamics in silicon nano-waveguides

Abstract

Carrier recombination dynamics in strip silicon nano-waveguides is analyzed through time-resolved pump-and-probe experiments, revealing a complex recombination dynamics at densities ranging from 1014 to 1017\,cm-3. Our results show that the carrier lifetime varies as recombination evolves, with faster decay rates at the initial stages (with lifetime of 800\,ps), and much slower lifetimes at later stages (up to 300\,ns). We also observe experimentally the effect of trapping, manifesting as a decay curve highly dependent on the initial carrier density. We further demonstrate that operating at high carrier density can lead to faster recombination rates. Finally, we present a theoretical discussion based on trap-assisted recombination statistics applied to nano-waveguides. Our results can impact the dynamics of several nonlinear nanophotonic devices in which free-carriers play a critical role, and open further opportunities to enhance the performance of all-optical silicon-based devices based on carrier recombination engineering.