Alignment-Free Angular Momentum Detection via Spin-Independent Astigmatic Transformation

Light beam carrying spin angular momentum (SAM) and orbital angular momentum (OAM) have attracted great interest due to their great potential for high-capacity optical communication, optical tweezers, and quantum information. However, the current detection methods suffer from the lack of robustness to misalignments in the optical system, which limits the detection accuracy and the application for off-axis vortex array detection. Here, a high-efficiency, broadband, and single-layer metasurface design is proposed for alignment-free angular momentum detection via spin-independent astigmatic transformation (SIAT). The SAM and OAM states can be recognized from the diffraction direction and patterns, respectively. Proof-of-concept demonstrations are experimentally carried out on different incident beams including circular-polarization, linear-polarization, and vector vortex beams, as well as vortex beam arrays, showing a high diffraction efficiency of & AP;81% at 1064 nm while operating within the broadband region of 900-1300 nm. The alignment-free merit for the incident position, incident angle, and detector distance grants the device great potential for integrated quantum systems and multiparticle micromanipulation with optical tweezers. A high-efficiency, broadband, and single-layer metasurface design is proposed for alignment-free angular momentum detection via spin-independent astigmatic transformation. The spin and orbital angular momentum can be recognized from the diffraction order and patterns, respectively. The alignment-free merit for the incident position, incident angle, and detector distance grants the device great potential for integrated quantum systems and multiparticle micromanipulation.image