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    Area of Science:

    • Optical engineering
    • Astronomy instrumentation

    Background:

    • Large-diameter diffractive lenses offer potential for space telescopes.
    • Chromatic aberrations in diffractive lenses limit performance by causing image blurring.

    Purpose of the Study:

    • To discuss solutions for reducing chromatic dispersion and aberrations in diffractive lenses.
    • To present a design example of a color corrector for a large-diameter diffractive lens.

    Main Methods:

    • A multi-order diffractive engineered lens (240-mm diameter, 1-m focal length) operating in the R-Band (589-727 nm) was designed.
    • A relay subsystem with refractive and diffractive elements was incorporated as a color corrector.

    Main Results:

    • The color corrector reduced longitudinal chromatic aberrations by over a factor of 30.
    • The system maintained the effective focal length and numerical aperture of the primary lens.
    • The design aims for diffraction-limited performance.

    Conclusions:

    • The proposed color corrector effectively mitigates chromatic aberrations in large-diameter diffractive lenses.
    • This solution enhances the feasibility of using diffractive optics in advanced space telescope designs.