Single-photon nonlinearity of a semiconductor quantum dot in a cavity

TL;DR

This paper demonstrates quantum nonlinearity at the single-photon level in a semiconductor quantum dot within a cavity, showing level splitting increases with photon number, advancing quantum optics on a chip.

Contribution

It provides the first evidence of true quantum nonlinearity in a quantum dot/cavity system, beyond classical or linear regimes.

Findings

Level splitting increases with photon number in the cavity.

Evidence of non-linear quantum effects at the single-photon scale.

Advances the use of quantum dots for quantum electrodynamics applications.

Abstract

A single atom in a cavity is the model system of cavity quantum electrodynamics (CQED). The strong coupling regime between the atom and cavity-confined photon corresponds to the reversible exchange of energy between the two modes, and underpins a wide range of CQED phenomena with applications in quantum information science, including for example as quantum logic gates and as sources of entangled states. An important advance was achieved recently when strong coupling between excitons and cavity photons was reported for the first time for localized quantum dots (QDs) in micron-size solid state cavities. This has significance in terms of scalability and integration with other optical devices, and could lead to the emergence of "quantum optics on a chip" technology. However the results presented so far for quantum dots are in the linear regime, corresponding to coupling to the vacuum field (vacuum Rabi splitting); they are not a true QED effect and can equally well be described by classical physics as the coupling between two oscillators. In this paper, we present evidence for a purely quantum phenomenon for the QD/cavity photon system, namely the increase in splitting of the levels when the mean number of photons in the cavity is increased. This corresponds to non-linearities on the single-photon scale: the presence of a single excitation in the cavity changes the level structure, affecting the emission energies for a second photon. Such results are a first step in demonstrating the promise of quantum dots for CQED applications.