APL Photonics (Oct 2024)

Broadband and widely tunable second harmonic generation in suspended thin-film LiNbO3 rib waveguides

  • Aiman Zinaoui,
  • Lucas Grosjean,
  • Arthur De Sousa Lopes Moreira,
  • Miguel Angel Suarez,
  • Samuel Queste,
  • Laurent Robert,
  • Ludovic Gauthier-Manuel,
  • Mathieu Chauvet,
  • Nadège Courjal

DOI
https://doi.org/10.1063/5.0230481
Journal volume & issue
Vol. 9, no. 10
pp. 101303 – 101303-8

Abstract

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Our study demonstrates second harmonic generation (SHG) in a high confinement LiNbO3 rib waveguide through type-I birefringence phase matching of fundamental modes. The combination of micro-waveguide dispersion and material birefringence reveals unique SHG characteristics that complement the performance of standard LiNbO3 on insulator (LNOI) components. Dual-pump wavelength phase matching in the near-infrared and mid-infrared regions is shown in a given waveguide. These two wavelengths can be positioned in the 1.1–3.5 μm range or converge near 1.5 μm by adjusting the core waveguide size or through temperature tuning. A 25 °C temperature change enables a broad pump tunability band of 300 nm, ranging from 1350 to 1650 nm, with a conversion efficiency exceeding 40 %/W/cm2 within a single waveguide. A temperature tuning range of up to 900 nm is foreseen by tailoring the waveguide core size. In addition, a broadband response of 150 nm within the telecom window is demonstrated experimentally. The nonlinear waveguide, etched in a thin film membrane, is combined with titanium-indiffused waveguides to form a monolithic LiNbO3 component. This configuration provides low coupling losses of 0.8 dB and single-mode operation. It paves the way for a new generation of versatile and cost-effective frequency conversion components with wide-band spectral responses suitable for optical communications, environmental sensing, and quantum information processing.