Suchergebnisse

We demonstrate third-harmonic generation (THG) in a dispersion-engineered slow-light photonic crystal waveguide fabricated in AMTIR-1 chalcogenide glass. Owing to the relatively low loss and low dispersion in the slow-light (c/30) regime, combined with the high nonlinear figure of merit of the material (∼2), we obtain a relatively large conversion efficiency (1.4×10(-8)/W(2)), which is 30× higher than in comparable silicon waveguides, and observe a uniform visible light pattern along the waveguide. These results widen the number of applications underpinned by THG in slow-light platforms, such as the direct observation of the spatial evolution of the propagating mode. ; This work was supported by the Centre of Excellence and Federation Fellowship programs of the Australian Research Council, as well as the School of Physics and the University of Sydney. We also acknowledge the European Union and the UK Engineering and Physical Sciences Research Council through the funding of the Slow Photon Light Activated Switch (SPLASH) project and the Silicon Photonics project.

We demonstrate third-harmonic generation (THG) in a dispersion-engineered slow-light photonic crystal waveguide fabricated in AMTIR-1 chalcogenide glass. Owing to the relatively low loss and low dispersion in the slow-light (c/30) regime, combined with the high nonlinear figure of merit of the material (∼2), we obtain a relatively large conversion efficiency (1.4×10(-8)/W(2)), which is 30× higher than in comparable silicon waveguides, and observe a uniform visible light pattern along the waveguide. These results widen the number of applications underpinned by THG in slow-light platforms, such as the direct observation of the spatial evolution of the propagating mode. ; This work was supported by the Centre of Excellence and Federation Fellowship programs of the Australian Research Council, as well as the School of Physics and the University of Sydney. We also acknowledge the European Union and the UK Engineering and Physical Sciences Research Council through the funding of the Slow Photon Light Activated Switch (SPLASH) project and the Silicon Photonics project.