The generation, manipulation, storage, and detection of single photons play a central role in
emerging photonic quantum information technology. Individual photons serve as flying …

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

Entanglement is a quintessential quantum mechanical phenomenon with no classical
equivalent. First discussed by Einstein, Podolsky, and Rosen and formally introduced by …

Epitaxial quantum dots formed by III–V compound semiconductors are excellent sources of
non-classical photons, creating single photons and entangled multi-photon states on …

On-chip chiral quantum light-matter interfaces, which support directional interactions,
provide a promising platform for efficient spin-photon coupling, nonreciprocal photonic …

Quantum states of light and matter can be manipulated on the nanoscale to provide a
technological resource for aiding the implementation of scalable photonic quantum …

Chiral quantum optics is a growing field of research where light-matter interactions become
asymmetrically dependent on momentum and spin, offering novel control over photonic and …

Non-reciprocal couplings or drivings are known to induce steady-state, directional,
amplification in driven-dissipative bosonic lattices. This amplification phenomena has been …

We present an inverse-design approach to significantly improve the figures of merit for chiral
photonics with quantum emitters in topological photonic crystal slab waveguides. Beginning …

A spin‐photon interface based on the luminescence of a singly charged quantum dot in a
micropillar cavity allows for the creation of photonic entangled states. Current devices suffer …