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Optically pumped microplasma rare gas laser.

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    Researchers developed a new continuous-wave (CW) optically pumped rare-gas metastable laser. This system utilizes electronically excited metastable argon atoms for laser oscillation at 912.3 nm, offering a chemically inert alternative.

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    Area of Science:

    • Atomic Physics
    • Laser Science
    • Plasma Physics

    Background:

    • Optically pumped alkali lasers rely on three-state systems.
    • Rare-gas metastable lasers offer a chemically inert alternative.
    • Efficient generation of metastable atoms is crucial for CW operation.

    Purpose of the Study:

    • To demonstrate CW optical gain and laser oscillation in a rare-gas metastable system.
    • To investigate the generation of metastable argon atoms using a micro-discharge.
    • To analyze the collisional energy transfer pathways within the argon metastable manifold.

    Main Methods:

    • Utilized a linear micro-discharge array for generating metastable Ar(4s, 1s(5)) atoms.
    • Operated gas mixtures at near atmospheric pressure under continuous-wave (CW) electric discharge.
    • Observed optical excitation at 811.5 nm and laser oscillation at 912.3 nm.
    • Employed a steady-state kinetics model to analyze collisional processes.

    Main Results:

    • Achieved CW optical gain and laser oscillation at 912.3 nm.
    • Successfully generated metastable Ar(4s, 1s(5)) atoms at atmospheric pressure.
    • Observed efficient 1s(5) → 2p(9) excitation and subsequent 2p(10) ↔ 1s(5) laser transition.
    • Kinetics model confirmed efficient collisional coupling within the Ar(4s) manifold.

    Conclusions:

    • Demonstrated the feasibility of CW optically pumped rare-gas metastable lasers.
    • The micro-discharge array is effective for generating necessary metastable species.
    • Collisional energy transfer plays a key role in the observed laser oscillation.