We study the collective radiative decay of a system of two two-level emitters coupled to a
one-dimensional waveguide in a regime where their separation is comparable to the …

Spontaneous light emission is central to a vast range of physical systems and is a founding
pillar for the theory of light–matter interactions. In the presence of complex photonic media …

Waveguides allow for direct coupling of emitters separated by large distances, offering a
path to connect remote quantum systems. However, when facing the distances needed for …

We propose a scheme aimed at achieving spatiospectral control over spontaneous emission
within a four-level atom-light coupling system interacting with optical vortices carrying orbital …

We investigate the dynamical evolution of the spontaneous emission of a two-level quantum
emitter near a graphene nanodisk. We employ the macroscopic quantum electrodynamics …

Orbital angular momentum (OAM) is an important property of vortex light, which provides a
valuable tool to manipulate the light-matter interaction in the study of classical and quantum …

Plasmons in nanostructured metals are widely utilized to trigger strong light-matter
interactions with quantum light sources. While the nonclassical behavior of such quantum …

In this Perspective, we present that polariton modes hosted in two-dimensional (2D)
materials can be used to increase and control light–matter interactions at the nanoscale. We …

As a quasiparticle formed by light and excitons in semiconductors, the exciton polariton (EP)
as a quantum bus is promising for the development of quantum interconnect devices at room …

We study the spontaneous emission (SPEM) for a quantum emitter (QUEM) near a
topological insulator Bi_2Se_3 nanosphere. We calculate numerically the QUEM Purcell …