After they have interacted, quantum particles generally behave as a single nonseparable
entangled system. The concept of entanglement plays an essential role in quantum physics …

Quantum computers hold the promise of solving certain computational tasks much more
efficiently than classical computers. We review recent experimental advances towards a …

The Jaynes–Cummings Model (JCM) has recently been receiving increased attention as
one of the simplest, yet intricately nonlinear, models of quantum physics. Emphasising the …

Microwave photons trapped in a superconducting cavity constitute an ideal system to realize
some of the thought experiments imagined by the founding fathers of quantum physics. The …

Entanglement is considered to be one of the most profound features of quantum mechanics,.
An entangled state of a system consisting of two subsystems cannot be described as a …

This paper reviews the work on cavity quantum electrodynamics of free atoms. In recent
years, cavity experiments have also been conducted on a variety of solid-state systems …

The possibility of creating and manipulating entangled states of systems of many particles is
of significant interest for quantum information processing; such a capability could lead to …

Interference phenomena are ubiquitous in physics, often forming the basis of demanding
measurements. Examples include Ramsey interferometry in atomic spectroscopy, X-ray …

Modern cavity quantum electrodynamics (cavity QED) illuminates the most fundamental
aspects of coherence and decoherence in quantum mechanics. Experiments on atoms in …

The steady increase in control over individual quantum systems supports the promotion of a
quantum technology that could provide functionalities beyond those of any classical device …