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Cord Arnold

Coordinator of Rydberg seminars

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Influence of the laser pulse duration in high-order harmonic generation

Author

  • Saga Westerberg
  • Melvin Redon
  • Ann-Kathrin Raab
  • Gaspard Beaufort
  • Marta Arias Velasco
  • Chen Guo
  • Ivan Sytcevich
  • Robin Weissenbilder
  • David P. O’Dwyer
  • Peter Smorenburg
  • Cord Arnold
  • A Lhuillier
  • Anne-Lise Viotti

Summary, in English

High-order harmonic generation (HHG) in gases is inherently inefficient, prompting ongoing efforts to enhance the output of coherent table-top XUV sources. In this study, we investigate the influence of the laser pulse duration on HHG using a compact post-compression method featuring a bulk multi-pass cell. This setup enables tunable Fourier-limited pulse durations as short as 42 fs. We examine the HHG yield as a function of the laser intensity for pulse durations ranging from 42 fs to 180 fs while maintaining identical focusing conditions and generating medium. Our findings reveal that, for a given intensity, there exists an optimum pulse duration -- not necessarily the shortest -- that maximizes conversion efficiency. This optimum pulse duration increases as the intensity decreases. The experimental results are corroborated by numerical simulations, which show the dependence of HHG yield on the duration and peak intensity of the driving laser and underscore the importance of the interplay between light-matter interaction and phase-matching in the nonlinear medium. Our conclusion allows us to understand why HHG could be demonstrated in 1988 with pulses as long as 40 ps pulses and intensities of only a few 1013 W/cm2.

Department/s

  • LTH Profile Area: Nanoscience and Semiconductor Technology
  • LU Profile Area: Light and Materials
  • NanoLund: Centre for Nanoscience
  • Atomic Physics
  • LTH Profile Area: Photon Science and Technology
  • Lund Laser Centre, LLC

Publishing year

2025

Language

English

Document type

Preprint (in preprint archive)

Publisher

arXiv.org

Topic

  • Atom and Molecular Physics and Optics

Status

Published