In this article, we review strong light-matter coupling at the interface of materials science,
quantum chemistry, and quantum photonics. The control of light and heat at thermodynamic …

The diversity of light-matter interactions accessible to a system is limited by the small size of
an atom relative to the wavelength of the light it emits, as well as by the small value of the …

A nanoantenna with balanced electric and magnetic dipole moments, known as the first
Kerker condition, exhibits a directive radiation pattern with zero backscattering. In principle …

Plasmon–emitter interactions are of central importance in modern nanoplasmonics and are
generally maximal at short emitter–surface separations. However, when the separation falls …

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 …

The unique properties of plasmonic nanostructures have fuelled research based on the
tremendous amount of potential applications. Their tailor‐made assemblies in combination …

Optical nanocavities have revolutionized the manipulation of radiative properties of
molecular and semiconductor emitters. Here, we investigate the amplified …

We numerically explore the emission behavior of magnetic dipole emitters located next to
resonant plasmonic split-ring resonators (SRRs), which are well known for their large …

In this paper, we will introduce THz graphene antennas that strongly enhance the emission
rate of quantum systems at specific frequencies. The tunability of these antennas can be …

We investigate the impact of light-forbidden exciton transitions in plasmon-emitter
interactions beyond the weak coupling regime. We consider a V-type quantum emitter, with …