With a bit of a delay today, here the most recent papers on Kerr frequency combs:
- Frigg, A. et al. Optical frequency comb generation with low temperature reactive sputtered silicon nitride waveguides. APL Photonics 5, 011302 (2020).
- Briles, T. C., Yu, S.-P., Drake, T. E., Stone, J. R. & Papp, S. B. Generating octave-bandwidth soliton frequency combs with compact, low-power semiconductor lasers. arXiv:2001.07775 (2020).
- Yang, J. et al. Coherent satellites in multispectral regenerative frequency microcombs. Commun Phys 3, 1–9 (2020).
- Zhao, Y. et al. Visible nonlinear photonics via high-order-mode dispersion engineering. Optica, OPTICA 7, 135–141 (2020).
- Raja, A. S. et al. Chip-based soliton microcomb module using a hybrid semiconductor laser. Opt. Express, OE 28, 2714–2721 (2020).
- Xu, X. et al. Soliton crystal 50G Hz micro-comb for Q-band microwave frequency conversion. techRxiv (2020) doi:10.36227/techrxiv.11530251.v1.
And below a few more interesting papers around the subject.
- Luo, K.-H. et al. Counter-propagating photon pair generation in a nonlinear waveguide. Opt. Express, OE 28, 3215–3225 (2020).
- Minet, Y. et al. Pockels-effect-based adiabatic frequency conversion in ultrahigh-Q microresonators. Opt. Express, OE 28, 2939–2947 (2020).
- Kuyken, B., Billet, M., Leo, F., Yvind, K. & Pu, M. Octave-spanning coherent supercontinuum generation in an AlGaAs-on-insulator waveguide. Opt. Lett., OL 45, 603–606 (2020).
- Hill, L. Effects of self- and cross-phase modulation on the spontaneous symmetry breaking of light in ring resonators. Phys. Rev. A 101, (2020).
- Lobanov, V. E., Kondratiev, N. M., Shitikov, A. E. & Bilenko, I. A. Two-color flat-top solitonic pulses in X(2) optical microresonators via second-harmonic generation. Phys. Rev. A 101, 013831 (2020).
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