Nonlinear Nanophotonic Chip-space Interfaces: On-chip Generation of Structured, Topological and Spatiotemporal Lights Via Nonlinear \v{C}erenkov Radiation

TL;DR

This paper demonstrates a novel integrated photonic platform using nonlinear renkov radiation in lithium niobate microring resonators to generate and control structured, topological, and spatiotemporal light on-chip with high reconfigurability.

Contribution

The work introduces a new method for on-chip generation of complex structured light using nonlinear renkov radiation in integrated microring resonators, enabling advanced control over light properties.

Findings

Successful on-chip generation of optical vortices with tunable properties

Generation of optical skyrmions and vortex microcombs in the visible range

Reconfigurable and tunable structured light beyond current state-of-the-art

Abstract

Miniaturized and reconfigurable interfaces between confined optical modes within integrated photonic chips and structured light propagating in free space would serve as a cornerstone for fundamental optical science and modern photonic technology. In this work, we exploit the anisotropic nonlinear susceptibility tensors associated with thin-film lithium niobate to construct nanophotonic chip-space interfaces capable of flexibly generating and multi-dimensionally engineering structured light via injections of photons to on-chip waveguides. By harnessing the nonlinear \v{C}erenkov radiation in integrated nonlinear microring resonators, we successfully tailor the spatial profile, polarization state, emission wavelength, topological charge and temporal wave packet of structured optical vortices, exhibiting reconfigurabilities and tuning ranges far beyond the state-of-the-art. To further showcase the capabilities of our platform, we use a single pump to generate tunable optical skyrmions via the spin-orbit coupling and multi-state integrated vortex microcombs in the visible range via synergistic $\chi^{(2)}$ and $\chi^{(3)}$ nonlinear optical processes. Our work bridges the research fields of structured light and integrated nonlinear optics, providing unprecedented opportunities for spatiotemporal light generation and on-chip multidimensional nonlinear optics.