Resolving proximal nanometer objects below the diffraction limit with interferometric phase intensity nanoscopy

The ability to spatially and temporally map nanoscale environments in situ over extended timescales would be transformative for biology, biomedicine, and bioengineering. All nanometer objects, from nanoparticles down to single proteins, scatter light. Interferometric scattering stands as a powerful tool, offering ultrasensitivity and resolution vital for visualizing nanoscale entities. Interferometric scattering from an individual nanoparticle down to an individual protein has been detected; however, resolving adjacent nanometer objects with interferometric scattering has not yet been demonstrated. In this work, we present interferometric phase intensity nanoscopy to resolve adjacent nanometer objects with interferometric scattering. We demonstrate that multiphase and sensitivity of interferometric phase intensity nanoscopy reveals ellipse Airy patterns correlated with nanostructural features. We show that eliminating background fluctuation by employing circular polarized illumination in interferometric phase intensity nanoscopy is essential to separate proximal nanometer objects below the diffraction limit. We envision interferometric phase intensity nanoscopy for resolving a variety of adjacent nanometer objects from nanoparticles down to proximal proteins in situ over extended time periods for wide range of applications in biology, biomedicine and bioengineering.