Simulation and design of dual-wavelength all-optical semiconductor optical amplifier with solution-processed quantum dots

Abstract

All-optical semiconductor optical amplifiers (SOAs) present a cost-effective and highly efficient solution for long-distance WDM networks. In this study, the investigation of a dual-wavelength all-optical SOA incorporating two distinct sizes of solution-processed InAs/AlAs core/shell quantum dots (QDs), operating at 1.31 and 1.55 μm wavelengths, both simultaneously and individually, has been proposed. To comprehensively evaluate the optical performance of our proposed dual-wavelength all-optical SOA, the modified coupled rate equations governing carriers dynamics and the optical photon propagation equations have been solved numerically while taking into account both homogeneous and inhomogeneous broadening, as well as fluorescence or förster resonance energy transfer (FRET) effects. This computational approach provides valuable insights into the optical behavior of dual-wavelength all-optical SOA. In our proposed structure, cost-effective solution-based methods for implementing QDs of varying sizes offer flexibility to adjust QD size across a broad range, from as small as 0.1 nm to meet specific requirements. This adjustment is made with meticulous consideration of appropriate synthesis techniques.