English

Tailoring microcombs with inverse-designed, meta-dispersion microresonators

Optics 2023-08-29 v3

Abstract

Nonlinear-wave mixing in optical microresonators offers new perspectives to generate compact optical-frequency microcombs, which enable an ever-growing number of applications. Microcombs exhibit a spectral profile that is primarily determined by their microresonator's dispersion; an example is the sech2 \operatorname{sech}^2 spectrum of dissipative Kerr solitons under anomalous group-velocity dispersion. Here, we introduce an inverse-design approach to spectrally shape microcombs, by optimizing an arbitrary meta-dispersion in a resonator. By incorporating the system's governing equation into a genetic algorithm, we are able to efficiently identify a dispersion profile that produces a microcomb closely matching a user-defined target spectrum, such as spectrally-flat combs or near-Gaussian pulses. We show a concrete implementation of these intricate optimized dispersion profiles, using selective bidirectional-mode hybridization in photonic-crystal resonators. Moreover, we fabricate and explore several microcomb generators with such flexible `meta' dispersion control. Their dispersion is not only controlled by the waveguide composing the resonator, but also by a corrugation inside the resonator, which geometrically controls the spectral distribution of the bidirectional coupling in the resonator. This approach provides programmable mode-by-mode frequency splitting and thus greatly increases the design space for controlling the nonlinear dynamics of optical states such as Kerr solitons.

Keywords

Cite

@article{arxiv.2209.10294,
  title  = {Tailoring microcombs with inverse-designed, meta-dispersion microresonators},
  author = {Erwan Lucas and Su-Peng Yu and Travis C. Briles and David R. Carlson and Scott B. Papp},
  journal= {arXiv preprint arXiv:2209.10294},
  year   = {2023}
}

Comments

16 pages, includes SI

R2 v1 2026-06-28T01:48:40.819Z