Degradation of III–V Quantum Dot Lasers Grown Directly on Silicon Substrates

Abstract: Initial age-related degradation mechanisms for InAs quantum dot lasers grown on silicon substrates emitting at 1.3 µm are investigated. The rate of degradation is observed to increase for devices operated at higher carrier densities and is therefore dependent on gain requirement or cavity length. While carrier localization in quantum dots minimizes degradation, an increase in the number of defects in the early stages of aging can increase the internal optical-loss that can initiate rapid degradation of laser p… Show more

“…Over the past few years, considerable progress has been made to achieve epitaxial growth of 1.3 μm QD lasers directly grown on Si, with in-depth research into optical properties and device reliability. [1][2][3][4] These lasers comprise of InAs QDs incorporated into layers of GaAs-based alloys which have ~4% lattice mismatch to Si. It is highly desirable to access the 1.55 μm lasing wavelength range to meet growing demands in siliconphotonics for long-haul optical communication and sensing technologies.…”

Optical gain and absorption of 1.55 μm InAs quantum dash lasers on silicon substrate

“…Over the past few years, considerable progress has been made to achieve epitaxial growth of 1.3 μm QD lasers directly grown on Si, with in-depth research into optical properties and device reliability. [1][2][3][4] These lasers comprise of InAs QDs incorporated into layers of GaAs-based alloys which have ~4% lattice mismatch to Si. It is highly desirable to access the 1.55 μm lasing wavelength range to meet growing demands in siliconphotonics for long-haul optical communication and sensing technologies.…”

Optical gain and absorption of 1.55 μm InAs quantum dash lasers on silicon substrate

“…9. The observed blue-shift may stem from a different potential profile of the QW active region on the Si substrate, carrier band-filling due to the higher threshold current density, and/or the potentially higher internal optical loss by a higher defect density [25]. Fig.…”

“…It must be noted that a significantly smaller slope efficiency was obtained from the device grown on Si substrate (η slope = 26.5mW/A), while those from the devices on either InP substrate or GaAs substrate were η slope = 174mW/A and η slope = 130mW/A, respectively. This observation can be indicative of a higher internal optical loss within the laser cavity, as a results of a higher defect density [25] and/or a significantly lower injection efficiency above the threshold, which can be greatly affected by the carrier leakage rate [26]. The carrier leakage rate can be, then, sensitive to the operation temperature, due to the nature of thermionic process.…”

Electrically injected 164µm emitting In₀₆₅Ga₀₃₅As 3-QW laser diodes grown on mismatched substrates by MOVPE

“…Based on these considerations, and on the experimental results in, , the optical degradation of QD LDs has to be modeled by considering a reduction in the injection efficiency. This reduction can be ascribed to the increase in carrier losses within the DWELL, which is mainly driven by the increase of defects close to the InGaAs well, ,,, which are responsible of enhancing the carrier losses affecting the QD reservoir (Figure ). According to previous investigations, the origin of the defects contributing to the increase in SRH recombination could be related to point defects participating to the recombination enhanced growth of pre-existent misfit dislocations, , such as As Ga or V As , , or, in general, to the extended defects themselves.…”

Addressing the Optical Degradation of 1.3 μm Quantum Dot Lasers through Subthreshold Characterization