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Phase optimization of dispersive mirrors based on floating constants.

M K Trubetskov1, V Pervak, A V Tikhonravov

  • 1Research Computing Center, Moscow State University, Moscow, Russia. trub@srcc.msu.ru

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A new phase-optimization technique enhances dispersive mirror stability, reducing sensitivity to errors. This method achieves high reflectivity (>99.99%) and precise dispersion control for optical applications.

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Area of Science:

  • Optics and Photonics
  • Materials Science

Background:

  • Dispersive mirrors are crucial optical components for controlling light dispersion.
  • Conventional design methods can be sensitive to fabrication errors, impacting performance.
  • Improving design stability is essential for reliable optical systems.

Purpose of the Study:

  • To develop a novel phase-optimization technique for dispersive mirrors.
  • To reduce the sensitivity of dispersive mirrors to layer thickness errors.
  • To demonstrate the improved design stability compared to conventional methods.

Main Methods:

  • A novel floating constants phase-optimization technique was developed.
  • The technique was applied to the design of dispersive mirrors.
  • Theoretical and experimental comparisons were made with conventional approaches.

Main Results:

  • The new technique significantly reduces sensitivity to layer thickness errors.
  • A fabricated dispersive mirror achieved >99.99% reflectivity.
  • Accurate dispersion control was demonstrated over a ~60 nm bandwidth.

Conclusions:

  • The novel phase-optimization technique offers superior design stability for dispersive mirrors.
  • This advancement enables more robust and reliable optical component fabrication.
  • The developed mirrors provide high performance for precise dispersion management.