Topological Nature of Radiation Asymmetry in Bilayer Metagratings (2401.12030v1)

Abstract: Manipulating radiation asymmetry of photonic structures is of particular interest in many photonic applications such as directional optical antenna, high efficiency on-chip lasers, and coherent light control. Here, we proposed a term of pseudo-polarization to reveal topological nature of radiation asymmetry in bilayer metagratings. Robust pseudo-polarization vortex with an integer topological charge exists in P-symmetry metagrating, allowing for tunable directionality ranging from -1 to 1 in synthetic parameter space. When P-symmetry-breaking, such vortex becomes pairs of C points due to the conservation law of charge, leading to the phase difference of radiation asymmetry from {\pi}/2 to 3{\pi}/2. Furthermore, topologically enabled coherent perfect absorption is robust with customized phase difference at will between two counter-propagating external light sources. This work can not only enrich the understanding of two particular topological photonic behavriors, i.e., bound state in the continuum and unidirectional guided resonance, but also provide a topological view on radiation asymmetry, opening an unexplored avenue for asymmetric light manipulation in on-chip laser, light-light switch and quantum emitters.