Nanophotonics offers opportunities for engineering and exploiting the quantum properties of
light by integrating quantum emitters into nanostructures, and offering reliable paths to …

Metasurfaces have recently risen to prominence in optical research, providing unique
functionalities that can be used for imaging, beam forming, holography, polarimetry, and …

Dicke superradiance in ordered atomic arrays is a phenomenon where atomic
synchronization gives rise to a burst in photon emission. This superradiant burst only occurs …

Spontaneous photon emission can be drastically modified by placing quantum emitters
(QEs) in nanostructured environment, resulting in dramatically enhanced emission rates due …

Atom arrays are a new type of quantum light-matter interface. Here we propose to employ
one-dimensional ordered arrays as atomic waveguides. These arrays support optical guided …

Ordered atomic arrays with subwavelength spacing have emerged as an efficient and
versatile light-matter interface, where collective interactions give rise to sets of super-and …

Subwavelength atomic arrays, recently labeled as quantum metamaterials, have emerged
as an exciting platform for obtaining novel quantum optical phenomena. The strong …

Superradiance and subradiance are collective effects that emerge from coherent
interactions between quantum emitters. Due to their many-body nature, theoretical studies of …

We develop a general framework for the analysis of two-sided quantum interfaces,
composed of collections of atoms interacting with paraxial light. Accounting for photon …

Directional emission of photons with designed polarizations and orbital angular momenta is
crucial for exploiting the full potential of quantum emitters (QEs) within quantum information …