แนวคิดหลัก
The authors experimentally measured the polarization helicity-dependent and helicity-independent transverse spin dynamics in the nonparaxial focal region of a high-numerical aperture lens by tracking the C-point polarization singularities in the retroreflected output beam.
บทคัดย่อ
The authors present an experimental study of the transverse spin dynamics in the nonparaxial focal region of a high-numerical aperture (NA) lens. They use a retroreflection geometry to map the nanoscale behavior of the state of polarization in the focal region.
Key highlights:
- The authors measure the phase and polarization variations in the retroreflected output beam as a function of the axial position of a dielectric mirror placed in the focal region.
- They identify phase and polarization singularities, such as edge-type dislocations, optical vortices, C-point and L-line singularities, in the beam cross-section.
- The dynamics of the C-point singularities and the surrounding polarization patterns are used to study the transverse spin dynamics.
- For right- and left-circular polarized input beams, the authors observe helicity-dependent and helicity-independent aspects of the transverse spin, including its rotation and radial movement in the focal region.
- The experimental method allows the authors to investigate the nonparaxial focal region in detail and unravel intricate optical field effects related to spin-orbit interaction of light.
สถิติ
The spatial (x, y) positions of the phase singular optical vortex (OV) points and the C-point polarization singularity (PS) measured in the output beam cross-section, for the mirror positions z± = ±λ/2 μm, are provided in Table 1.
คำพูด
"The capability of our method to measure and identify edge- and vortex-type phase singularities in the focal region of the high-NA lens with sub-pixel accuracy is thus demonstrated."
"The measured characteristics and their behaviour confirm helicity-dependent SD and the spin-momentum coupling that appears in the high-NA lens´ focal region."