We have investigated, theoretically and experimentally the nonlinear dynamics of quadratic resonators.
Theoretically, we uncovered many novel configurations for frequency comb generation that were prevoioulsy unknown.
To confirm these experimentally, we built two novel experimental platforms for frequency comb generation, namely acivte fiber resonators and gallium phosphide-on-insulator.
The first was achived earlier in the project and has been used for several important advances in the field of frequency comb generation and soliton formation
• N. Englebert, C. Mas Arabí, P. Parra-Rivas, S.-P. Gorza, and F. Leo, Temporal Solitons in a Coherently Driven Active Resonator, Nature Photonics 15, 536 (2021).
• N. Englebert, F. De Lucia, P. Parra-Rivas, C. M. Arabí, P.-J. Sazio, S.-P. Gorza, and F. Leo, Parametrically Driven Kerr Cavity Solitons, Nat. Photon. 15, 857 (2021).
• N. Englebert, N. Goldman, M. Erkintalo, N. Mostaan, S.-P. Gorza, F. Leo, and J. Fatome, Bloch Oscillations of Driven Dissipative Solitons in a Synthetic Dimension, to appear in Nat. Phys (2023)
The second was more challenging but we recently achieved the fabrication of high quality waveguides and resonators which will be suitable for frequency comb generation.
• M. Billet et al., Gallium Phosphide-on-Insulator Integrated Photonic Structures Fabricated Using Micro-Transfer Printing, Opt. Mater. Express 12, 3731 (2022).
We are currently actively working on both platforms to further advance the field of optical frequency combs.