The PBG group of Department of physics, Fudan university, recently proposed a method using a reflective photonic crystal slab to generate vortex with high conversion efficiency and without an alignment center.
Researchers utilize the polarization singularity located at the at-Γ bound state in the continuum in the momentum space to generate the vortex beam. Since the singularity exists in the momentum space, the working region of the photonic crystal slab doesn’t rely on the incident position of the beam.
To push the conversion efficiency of the generator, researchers firstly introduced a perfect mirror to block the transmission channels in nonlocal vortex beam generation systems, which will then only transfer the incident energy to the reflection channel. They found that VB generation using single resonances and a perfect mirror in a reflection-type system can achieve 100% cross-polarized conversion efficiency. Unfortunately, when the practical applications at visible and near-infrared wavelengths are considered, the absorption of the metal mirror will inevitably cause a loss that will reduce the conversion efficiency of such a vortex beam generator greatly. In this work, they gave a general picture based on temporal coupled mode theory to improve the VB generation efficiency of reflection-type generators with intrinsic absorption. In their theory, the conversion efficiency was determined by the ratio of the radiative loss to the intrinsic absorption. Based on this picture, mode selection and structure design are employed to increase this ratio efficiently. In both simulations and experiments, they observed the maximum on-resonance conversion efficiency of up to 86% in their designed reflection-type vortex beam generators. They also experimentally observed the vortex beam profiles generated at different wavelengths and in different working regions.
See the article:
High-efficiency nonlocal reflection-type vortex beam generation based on bound states in the continuum
National Science Review