Nature Communications (Sep 2024)

Ultraviolet astronomical spectrograph calibration with laser frequency combs from nanophotonic lithium niobate waveguides

  • Markus Ludwig,
  • Furkan Ayhan,
  • Tobias M. Schmidt,
  • Thibault Wildi,
  • Thibault Voumard,
  • Roman Blum,
  • Zhichao Ye,
  • Fuchuan Lei,
  • François Wildi,
  • Francesco Pepe,
  • Mahmoud A. Gaafar,
  • Ewelina Obrzud,
  • Davide Grassani,
  • Olivia Hefti,
  • Sylvain Karlen,
  • Steve Lecomte,
  • François Moreau,
  • Bruno Chazelas,
  • Rico Sottile,
  • Victor Torres-Company,
  • Victor Brasch,
  • Luis G. Villanueva,
  • François Bouchy,
  • Tobias Herr

DOI
https://doi.org/10.1038/s41467-024-51560-x
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Astronomical precision spectroscopy underpins searches for life beyond Earth, direct observation of the expanding Universe and constraining the potential variability of physical constants on cosmological scales. Laser frequency combs can provide the required accurate and precise calibration to the astronomical spectrographs. For cosmological studies, extending the calibration with such astrocombs to the ultraviolet spectral range is desirable, however, strong material dispersion and large spectral separation from the established infrared laser oscillators have made this challenging. Here, we demonstrate astronomical spectrograph calibration with an astrocomb in the ultraviolet spectral range below 400 nm. This is accomplished via chip-integrated highly nonlinear photonics in periodically-poled, nano-fabricated lithium niobate waveguides in conjunction with a robust infrared electro-optic comb generator, as well as a chip-integrated microresonator comb. These results demonstrate a viable route towards astronomical precision spectroscopy in the ultraviolet and could contribute to unlock the full potential of next-generation ground-based and future space-based instruments.