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Carrier Generation and Recombination01:22

Carrier Generation and Recombination

868
Carrier generation is the process by which electron-hole pairs (EHPs) are created within the semiconductor. In direct-bandgap semiconductors, such as gallium arsenide (GaAs), this occurs efficiently when energy absorption prompts valence electrons to leap into the conduction band, leaving behind holes.
This process is given by the generation rate G and is efficient due to the conservation of momentum between the valence band maximum and conduction band minimum.
Indirect generation involves an...
868
Carrier Transport01:21

Carrier Transport

631
The generation of electrical current in semiconductors is fundamentally driven by two mechanisms: drift and diffusion. These processes are essential for the functionality and performance of semiconductor-based devices.
Drift Current:
The drift of charge carriers is started by an external electric field (E). Charged particles, such as electrons and holes, experience an acceleration between collisions with lattice atoms. For electrons, this results in a drift velocity (vd) given by:
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Related Experiment Video

Updated: Oct 12, 2025

Measurement of Quantum Interference in a Silicon Ring Resonator Photon Source
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Phase diffusion in gain-switched semiconductor lasers for quantum random number generation.

Ana Quirce, Angel Valle

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    |November 23, 2021
    PubMed
    Summary

    Nonlinear effects in semiconductor lasers are crucial for understanding phase diffusion. Considering logarithmic gain and cubic recombination is essential for accurate theoretical modeling of laser behavior.

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    Area of Science:

    • Physics
    • Quantum Optics
    • Semiconductor Lasers

    Background:

    • Phase diffusion in semiconductor lasers is critical for applications like quantum random number generation.
    • Previous models often used linear approximations for carrier recombination and material gain.

    Purpose of the Study:

    • To theoretically and experimentally investigate phase diffusion in a gain-switched single-mode semiconductor laser.
    • To evaluate the impact of nonlinear dependencies on carrier recombination and material gain.
    • To compare results with linear models.

    Main Methods:

    • Developed a theoretical model incorporating nonlinear dependencies of carrier recombination and material gain on carrier number.
    • Conducted experimental studies on a gain-switched single-mode semiconductor laser.
    • Analyzed phase diffusion, particularly in the below-threshold regime.
    • Utilized analytical expressions for laser linewidth.

    Main Results:

    • Logarithmic material gain and cubic carrier recombination dependence on carrier number are necessary for accurate theoretical predictions.
    • Nonlinear models provide a significantly better agreement with experimental data compared to linear models.
    • Phase diffusion is most pronounced in the below-threshold operation regime.

    Conclusions:

    • Accurate modeling of phase diffusion in semiconductor lasers requires incorporating nonlinearities in carrier recombination and material gain.
    • The study highlights the importance of these nonlinearities for quantitative descriptions using rate equation modeling.
    • Findings are essential for optimizing semiconductor lasers in quantum random number generation.