Optical metamaterials have presented an innovative method of manipulating light.
Hyperbolic metamaterials have an extremely high anisotropy with a hyperbolic dispersion …

The spin Hall effect of light (SHEL) is the microscopic splitting of light into two circular
polarizations at the optical interface along the perpendicular direction. With the advent of …

The spin Hall effect of light refers to a spin-dependent transverse splitting of light at a planar
interface. Previous demonstrations to enhance the splitting have suffered from exceedingly …

The photonic spin Hall effect (PSHE) plays an important role in both fundamental science
and precision metrology. In this paper, we theoretically propose a polarization-dependent …

Optical spin-Hall effect (SHE) exhibits many intriguing features as a linearly polarized (LP)
light beam strikes an interface at incident angles around the Brewster angle, but the …

The spin Hall effect of light (SHEL) refers to a transverse and spin‐dependent shift of light in
real space at an optical interface. Previous studies of enhancing the SHEL have involved …

Artificial chiral structures have potential applications in the field of enantioselective signal
sensing. Advanced nanofabrication methods enable a large diversity in geometric structures …

Optical image processing based on the photonic spin Hall effect (SHE) has been gaining
significant attention as a convenient and an accurate way for image edge detection …

Sub-10 nm nanostructures have received broad interest for their intriguing nano-optical
phenomena, such as extreme field localization and enhancement, quantum tunneling effect …

The spin Hall effect of light (SHEL), which refers to a spin‐dependent and transverse
splitting of refraction and reflection phenomena, inherently depends on the polarization …