Quantum plasmonics is a rapidly growing field of research that involves the study of the
quantum properties of light and its interaction with matter at the nanoscale. Here, surface …

Surface plasmons allow electromagnetic fields to be confined to subwavelength scale, well
beyond the classical optical diffraction limit. With continuous reduction of optical mode …

Efficient light-matter interaction lies at the heart of many emerging technologies that seek on-
chip integration of solid-state photonic systems. Plasmonic waveguides, which guide the …

There have recently been remarkable achievements in turning light–matter interaction into
strong-coupling quantum regime. In particular, room-temperature plexcitonic strong coupling …

Entanglement-based quantum science exploits subtle properties of quantum mechanics into
applications such as quantum computing, sensing, and metrology. The emerging route for …

We model the quantum dynamics of two, three, or four quantum dots (QDs) in proximity to a
plasmonic system such as a metal nanoparticle or an array of metal nanoparticles. For all …

Frontier quantum engineering tasks require reliable control over light-matter interaction
dynamics, which could be obtained by introducing electromagnetic structuring. Initiated by …

This review is devoted to the study of effects of quantum optics in nanostructures. The
mechanisms by which the rates of radiative and nonradiative decay are modified are …

A scheme is proposed to generate a maximally entangled state between two qubits by
means of a dissipation-driven process. To this end, we entangle the quantum states of qubits …

Entanglement between two qubits (two level atoms) mediated by surface plasmons in three-
dimensional plasmonic waveguides is studied using a quantum master equation formalism …