Thickness-dependent slow light gap solitons in three-dimensional coupled photonic crystal waveguides

The thickness-dependent multimodal nature of threedimensional (3D) coupled photonic crystal waveguides is investigated with the aim of realizing a medium for controlled optical gap soliton formation in the slow light regime. In the linear case, spectral properties of the modes (dispersion diagrams), location of the gap regions versus the thickness of the 3D photonic crystal, and the near-field distributions at frequencies in the slowlight region are analyzed using a full-wave electromagnetic solver. In the nonlinear regime (Kerr-type nonlinearity), we infer an existence of crystal-thickness-dependent temporal solitons with stable pulse envelope and use the solitonic pulses for driving quantum transitions in localized quantum systems within the photonic crystal waveguide. The results may be useful for applications in optical communications, multiplexing systems, nonlinear physics, and ultrafast spectroscopy. (C) 2022 Optica Publishing Group

Automated summary

The thickness-dependent multimodal nature of three-dimensional coupled photonic crystal waveguides is investigated for the formation of controlled optical gap solitons. Both linear and nonlinear behaviors are studied, revealing the spectral properties and temporal solitons associated with crystal thickness.