Blue-shifted dispersive waves and broadband UV emission using dual-core SiN waveguides

TL;DR

This paper demonstrates that dual-core silicon nitride waveguides can generate supercontinuum light with blue-shifted dispersive waves and broadband UV emission, outperforming single-core waveguides in wavelength extension and efficiency.

Contribution

The study introduces a dual-core waveguide design that shifts dispersive wave wavelengths towards the UV range and enhances broadband generation, with experimental and numerical validation.

Findings

Blue-shifted dispersive waves at 540 nm in dual-core waveguides

Broadband UV emission below 350 nm achieved

Good agreement between experiments and simulations

Abstract

We show that using strongly coupled dual-core waveguides for supercontinuum generation shifts the wavelength of the high-frequency dispersive waves towards shorter wavelengths, as compared to generation in a single-core waveguide having the same core dimensions. In a demonstration experiment, we launch ultrashort infrared pump pulses at 1-$\mu$m wavelength (285-THz frequency) into silicon nitride waveguides, where soliton formation and fission leads to generation of dispersive waves in the visible range. Efficient input coupling and controlled excitation of the fundamental supermodes of the dual-core waveguide is provided with adiabatic tapers and a dual-prong input structure. For the dual-core waveguide, the short-wavelength dispersive wave is located at 540~nm (green, 555~THz), which is blue-shifted by 80~nm (70~THz) compared to that of the single-core waveguide. Simultaneously, the dual-core waveguide generates broadband radiation spanning from the blue into the UV range, reaching to below 350~nm (above 855~THz), with typically a spectral density 25~dB below that of the dispersive wave. The broadband component can be addressed to third harmonic generation and is not observed in single-core supercontinuum generation. Numerical modeling shows good agreement with experimental measurements. The demonstrated dual-core approach and dedicated input coupling appear to hold promise also for other waveguide structures, independent of specific materials or core dimensions, by providing shorter wavelengths than with the respective single-core waveguide.