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Stochastic Simulator for modeling the transition to lasing.

G P Puccioni, G L Lippi

    Optics Express
    |April 4, 2015
    PubMed
    Summary
    This summary is machine-generated.

    A new Stochastic Simulator (SS) models the lasing transition efficiently for all laser sizes. It accurately predicts steady-state behavior and reveals the crucial role of fluctuations near the lasing threshold.

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    Area of Science:

    • Quantum optics
    • Laser physics
    • Computational physics

    Background:

    • Understanding the lasing transition is crucial for laser development.
    • Existing models may lack efficiency or detailed fluctuation analysis, especially for nanoscale devices.

    Purpose of the Study:

    • To introduce an efficient Stochastic Simulator (SS) for modeling the lasing transition.
    • To provide a unified description for devices from nanolasers to macroscopic lasers.
    • To investigate the role of fluctuations in the lasing process.

    Main Methods:

    • Developed a Stochastic Simulator (SS) based on a semiclassical radiation-matter interaction model.
    • Compared SS steady-state predictions with traditional laser modeling.
    • Analyzed dynamical information and fluctuations at the lasing threshold.

    Main Results:

    • SS predictions align with traditional models for steady-state behavior.
    • SS accurately describes phase transitions in small-sized systems.
    • The simulator efficiently provides dynamical information, highlighting the significance of fluctuations at threshold.

    Conclusions:

    • The Stochastic Simulator offers an efficient and accurate method for studying the lasing transition across various scales.
    • The SS provides valuable insights into system fluctuations, particularly near the lasing threshold.
    • This approach enhances the understanding of both nanolasers and traditional lasers.