Modelling Markovian light-matter interactions for quantum optical devices in the solid state

Abstract: The desire to understand the interaction between light and matter has stimulated centuries of research, leading to technological achievements that have shaped our world. One contemporary frontier of research into light-matter interaction considers regimes where quantum effects dominate.By understanding and manipulating these quantum effects, a vast array of new quantum-enhanced technologies become accessible. In this thesis, I explore and analyze fundamental components and processes for quantum optical devices… Show more

“…As we will see in the rest of the review, the implementation of performant single-photon sources demands good optical cavities (high-quality factor, small mode volume) in the Purcell regime. [92] These cavities can be implemented via different approaches, such as Fabry-Pérot-like cavities (with two opposing concave mirrors enclosing a resonant spacer, as seminally done with natural atoms), photonic crystal cavities, or plasmonic-like devices (such as bullseye resonators or nanoantennas where plasmonic near-fields can be tightly confined at protrusions with deep sub-wavelength radii of curvature). Different cavity approaches, with their specific properties and different regimes of operation, can be consulted in other reviews.…”

Solid‐State Single‐Photon Sources: Recent Advances for Novel Quantum Materials

“…As we will see in the rest of the review, the implementation of performant single-photon sources demands good optical cavities (high-quality factor, small mode volume) in the Purcell regime. [92] These cavities can be implemented via different approaches, such as Fabry-Pérot-like cavities (with two opposing concave mirrors enclosing a resonant spacer, as seminally done with natural atoms), photonic crystal cavities, or plasmonic-like devices (such as bullseye resonators or nanoantennas where plasmonic near-fields can be tightly confined at protrusions with deep sub-wavelength radii of curvature). Different cavity approaches, with their specific properties and different regimes of operation, can be consulted in other reviews.…”

Solid‐State Single‐Photon Sources: Recent Advances for Novel Quantum Materials