Trimming and ultra-wide bandwidth expansion of silicon frequency comb spectra with self-adaptive boundary waveguides
Jianhao Zhang, Vincent Pelgrin, Carlos Alonso-Ramos, Laurent Vivien,, Sailing He, and Eric Cassan

TL;DR
This paper introduces a novel dispersion engineering method using self-adaptive boundary waveguides to significantly expand and trim silicon frequency comb spectra, enhancing bandwidth and phase matching for nonlinear applications.
Contribution
It presents a new approach to dispersion engineering with self-adaptive boundary waveguides, enabling ultra-wide bandwidth frequency combs in silicon photonics.
Findings
Demonstrated theoretical bandwidth improvements over existing methods
Enabled low-anomalous dispersion across large wavelength ranges
Applicable to high-index-contrast platforms for nonlinear applications
Abstract
Dispersion engineering is among the most important steps towards a promising optical frequency comb. We propose a new and general approach to trim frequency combs using a self-adaptive boundary of the optical mode at different wavelengths in a sub-wavelength structured waveguide. The feasibility of ultra-wide bandwidth dispersion engineering comes from the fact that light at different wavelengths automatically self-adapts to slightly different effective spatial spans determined by the effective indices of the mode. Using this self-adaptive variation on the confinement, we open up the window of low-anomalous dispersion in a large wavelength range, and theoretically demonstrate frequency combs with improved bandwidths with respect to the state-of-art in several different waveguide configurations considered, for a matter of illustration, in the silicon photonic platform. This strategy…
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Taxonomy
TopicsAdvanced Fiber Laser Technologies · Photonic and Optical Devices · Photonic Crystal and Fiber Optics
