Direct observation of photonic spin Hall effect in Mie scattering

The photonic spin Hall effect, a hallmark of spin-orbit interaction in light, has emerged as a platform for spin-dependent applications in nanophotonics. Due to intrinsic weak spin-orbit interaction, the resultant shift is tiny with drastically low scattering efficiency, which necessitates signal amplification and high-precision weak measurements for detection - often at the cost of further lowering the intensity. This dilemma between the photonic spin Hall shift and the scattered intensity becomes even more pronounced when the geometry shrinks to the scale of a single particle. Here, we overcome this dilemma by breaking the rotational symmetry of the scatterer to induce multipolar coupling along with strong spin-orbit coupling, resulting in superscattering that boosts the scattering intensity at the maximal photonic spin Hall shift by two orders of magnitude compared to conventional dipolar particle. By tailoring the multipolar interference, the photonic spin Hall shift is enhanced at an angle feasible for direct observation. In doing so, we perform a post-selection-free experiment to bypass the loss in intensity and preserve both the spin Hall shift and the scattering efficiency. We have, for the first time, experimentally demonstrated the predicted photonic spin Hall shift for a standalone particle through measurable differences in far-field scattering intensity in the microwave regime. These findings pave the way for a deeper exploration of the spin Hall effect of light and open new avenues for applications in precision metrology and advanced optical imaging.