Nanostructured materials offer the possibility to tailor light–matter interaction at scales below
the wavelength. Metallic nanostructures benefit from the excitation of surface plasmons that …

Tailoring of electromagnetic spontaneous emission predicted by EM Purcell more than 50
years ago has undoubtedly proven to be one of the most important effects in the rich areas of …

Assembling metamolecules from anisotropic, shape-engineered nanocrystals provides the
opportunity to orchestrate distinct optical responses one nanocrystal at a time. The Au …

The reflection of an optical wave from metal, arising from strong interactions between the
optical electric field and the free carriers of the metal, is accompanied by a phase reversal of …

Tremendous advances in the study of magnetic light-matter interactions have recently been
achieved using man-made nanostructures that exhibit and exploit an optical magnetic …

Given growing interest in optical-frequency magnetic dipole transitions, we use intermediate
coupling calculations to identify strong magnetic dipole emission lines that are well suited for …

Assemblies of strongly coupled plasmonic nanoparticles can support highly tunable electric
and magnetic resonances in the visible spectrum. In this Letter, we theoretically demonstrate …

The concentration and manipulation of light in the nanoscale range are fundamental to
nanophotonic research. Plasmonic nanoparticles can localize electromagnetic waves within …

We demonstrate that magnetic dipole transitions provide an additional degree of freedom for
engineering emission spectra. Without the need for a high-quality optical cavity, we show …

Mie resonances in dielectric particles can increase the local optical density of states (LDOS)
associated with either electric or magnetic transition rates in nearby quantum emitters …