The coherent interaction between quantum emitters and photonic modes in cavities
underlies many of the current strategies aiming at generating and controlling photonic …

Localizing light to nanoscale volumes through nanoscale resonators that are low loss and
precisely tailored in spectrum to properties of matter is crucial for classical and quantum light …

An emitter in the vicinity of a metal nanostructure is quenched by its decay through
nonradiative channels, leading to the belief in a zone of inactivity for emitters placed within< …

Plasmonic cavities can be used to control the atom-photon coupling process at the
nanoscale, since they provide an ultrahigh density of optical states in an exceptionally small …

Interactions between a single emitter and cavity provide the archetypical system for
fundamental quantum electrodynamics. Here we show that a single molecule of Atto647 …

Optical cavities can enhance and control light-matter interactions. This level of control has
recently been extended to the nanoscale with single emitter strong coupling even at room …

The large losses of plasmonic nanocavities, orders of magnitude beyond those of photonic
dielectric cavities, places them, perhaps surprisingly, as exceptional enhancers of single …

Plasmonic self-assembled nanocavities are ideal platforms for extreme light localization as
they deliver mode volumes of< 50 nm3. Here we show that high-order plasmonic modes …

As the size of a molecular emitter becomes comparable to the dimensions of a nearby
optical resonator, the standard approach that considers the emitter to be a point-like dipole …

Plasmonic cavities can confine electromagnetic radiation to deep sub-wavelength regimes.
This facilitates strong coupling phenomena to be observed at the limit of individual quantum …