Furthermore, potentially useful output powers of up to 50 mW were observed from the narrow facet of the SLD, which could again be exploited via single device multiplexing to increase output power, with little to no cost to spectral bandwidth. The experimental findings were analyzed using a rate-equation based QD model considering the QD ensemble inhomogeneous broadening, the multilayer chirped active material, the spatial distribution of the QD carriers and the spectral and spatial distribution of the photons in the SLDs. The numerical simulations were able to predict the asymmetric output powers extracted from the SLD facets, mainly to due to different equivalent material losses experienced by the forward and backward fields in the weakly gain guided tapered device. Simulations were also able to predict the spectral distribution of the optical fields at the output facets. |
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Waveguides
Multiplexing
Superluminescent diodes
Numerical simulations
Photons
Picosecond phenomena
Optical simulations