Mixing second- and third-order nonlinear interactions in nanophotonic lithium-niobate waveguides

In this paper, we investigate the interplay between the second- and the third-order nonlinearities in lithium-niobate waveguides with strong waveguide dispersion using uniform and linearly chirped poling patterns at input powers in the picojoule range. We implement the accurate unidirectional pulse propagation model to take into account all the possible nonlinear interactions inside these structures. In particular, the poling period is designed to quasi-phase-match single and multiple sum- and difference-frequency generation processes. We show how the poling period can be used as an additional degree of freedom to transform the output spectra of chip-based nonlinear waveguides in an unprecedented way.

Automated summary

This paper investigates the relationship between second- and third-order nonlinearities in lithium-niobate waveguides, using uniform and linearly chirped poling patterns. The results show that the poling period can be used to transform the output spectra in a unique way.