Silicon photonics-based high-energy passively Q-switched laser Journal Articles uri icon

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abstract

  • AbstractChip-scale, high-energy optical pulse generation is becoming increasingly important as integrated optics expands into space and medical applications where miniaturization is needed. Q-switching of the laser cavity was historically the first technique to generate high-energy pulses, and typically such systems are in the realm of large bench-top solid-state lasers and fibre lasers, especially in the long wavelength range >1.8 µm, thanks to their large energy storage capacity. However, in integrated photonics, the very property of tight mode confinement that enables a small form factor becomes an impediment to high-energy applications owing to small optical mode cross-sections. Here we demonstrate a high-energy silicon photonics-based passively Q-switched laser with a compact footprint using a rare-earth gain-based large-mode-area waveguide. We demonstrate high on-chip output pulse energies of >150 nJ and 250 ns pulse duration in a single transverse fundamental mode in the retina-safe spectral region (1.9 µm), with a slope efficiency of ~40% in a footprint of ~9 mm2. The high-energy pulse generation demonstrated in this work is comparable to or in many cases exceeds that of Q-switched fibre lasers. This bodes well for field applications in medicine and space.

authors

  • Singh, Neetesh
  • Lorenzen, Jan
  • Sinobad, Milan
  • Wang, Kai
  • Liapis, Andreas C
  • Frankis, Henry C
  • Haugg, Stefanie
  • Francis, Henry
  • Carreira, Jose
  • Geiselmann, Michael
  • Gaafar, Mahmoud A
  • Herr, Tobias
  • Bradley, Jonathan
  • Sun, Zhipei
  • Garcia-Blanco, Sonia M
  • Kärtner, Franz X

publication date

  • May 2024