Abstract
Phase and polarization singularities are important degrees of freedom for electromagnetic field manipulation. Detecting these singularities is essential for modern optics, but it is still a challenge, especially in integrated optical systems. In this paper, we propose an on-chip plasmonic spin-Hall nanograting structure that simultaneously detects both the polarization and phase singularities of the incident cylindrical vortex vector beam (CVVB). The nanograting is symmetry-breaking with different periods for the upper and lower parts, which enables the unidirectional excitation of the surface plasmon polariton depending on the topological charge of the incident optical vortex beam. Additionally, spin-Hall meta-slits are integrated onto the grating so that the structure has a chiral response for polarization detection. We demonstrate theoretically and experimentally that the designed structure fully discriminates both the topological charges and polarization states of the incident beam simultaneously. The proposed structure has great potential in compact integrated photonic circuits.
Highlights
Optical singularities are key elements in modern optics and have been widely researched
A symmetry-breaking nanograting structure was designed first to unidirectionally launch the surface plasmon polariton (SPP) wave according to the sign of the topological charge of the incident wave
The propagation angle of the generated SPP increases with the value of the topological charge
Summary
Optical singularities are key elements in modern optics and have been widely researched. Phase and polarization singularities have been manipulated in various applications, such as imaging and metrology[1], nonlinear optics[2], optical tweezers[3], sensing[4], quantum information[5,6], and optical communication[7,8]. The phase singularity of an optical field was first theoretically and experimentally demonstrated in the 1970s9. The optical vortex (OV) has been the most widely used optical beam with a phase singularity. The unique properties of the OV, such as a spiral phase wave front, orbital angular momentum (OAM), and donutshaped intensity distribution, have been used for optical. The unique spatial intensity distribution, especially in focusing, has advantages in imaging and lithography[12].
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