Resolving Complex Subwavelength Grating Structures Using Topologically Structured Light

It has been seen recently that when probing a nanoscale object to determine, for example, size or position via light scattering, significant advantage in measurement precision can be gained from exploiting phase singularities in a topologically structured incident light field. Here, we demonstrate that this advantage, derived from the dependence of scattered intensity profiles on strong local (subwavelength-scale) intensity and phase variations in the incident field, can be extended towards imaging applications: Analysis of scattering patterns from arbitrary binary gratings under superoscillatory illumination successfully resolves feature sizes down to ~λ/7 in single-shot measurements (a factor of 1.4x smaller than is achieved with plane wave illumination), and ~λ/10.5 in positionally-displaced multi-shot measurements (which yields no improvement in the plane wave case). Interestingly, there are circumstances in which more complex objects are better resolved than simple structures, because interference effects increase the information content of their scattering patterns.