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Investigation of Early Plasma Evolution Induced by Ultrashort Laser Pulses
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Spatial-domain interferometer for measuring plasma mirror expansion.

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    We developed a new interferometer to measure the electronic density gradient of plasma mirrors with high temporal resolution. This technique enables ultrafast imaging of laser-induced phenomena at surfaces.

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    Area of Science:

    • Plasma Physics
    • Ultrafast Optics
    • Interferometry

    Background:

    • Laser-induced plasma mirrors are crucial for high-intensity laser-plasma interactions.
    • Characterizing the electronic density gradient is essential for understanding plasma dynamics.
    • Existing methods lack sufficient temporal resolution for ultrafast phenomena.

    Purpose of the Study:

    • To present a practical spatial-domain interferometer (SDI) for characterizing plasma mirrors.
    • To achieve sub-30-femtosecond temporal resolution in measurements.
    • To enable ultrafast imaging of laser-induced phenomena at surfaces.

    Main Methods:

    • Utilized time-resolved spatial imaging of an intensity-shaped pulse reflecting off a plasma mirror.
    • Employed a time-delayed pre-pulse to induce the expanding plasma mirror.
    • Developed a spatial-domain interferometer (SDI) for high-resolution measurements.

    Main Results:

    • Successfully measured characteristic plasma gradients of 10-100 nm.
    • Determined an expansion velocity of 10.8 nm/ps for the plasma mirror.
    • Demonstrated the capability for sub-30-femtosecond temporal resolution.

    Conclusions:

    • Spatial-domain interferometry (SDI) is a practical method for characterizing plasma mirrors.
    • The developed technique allows for precise measurement of plasma density gradients.
    • SDI can be generalized for ultrafast imaging of various laser-induced surface phenomena.