Cavity Quantum Electrodynamics with Site-Controlled Pyramidal Quantum Dots in Photonic Crystal Cavities

Cavity quantum electrodynamics encompasses the study and control of the interactions between quantum light sources and resonant modes of optical cavities. The subject of this thesis is cavity quantum electrodynamics with semiconductor quantum dots (QDs), which are light-emitting nanostructures with atom-like optical and electronic properties. Recently it has become possible to combine QDs with methods of producing cavities that have microscopically small volumes, which led to the observations of spontaneous emission enhancement, lasing, single-photon nonlinearities and vacuum Rabi splitting. These effects can potentially be exploited for applications in quantum communication, computing and metrology. A challenging obstacle faced in current research is the lack of control over the positions of the QDs within the cavity structures, because the majority of experiments employ self-assembled QDs that nucleate randomly at unpredictable locations during the crystal growth process. The technical objective of the present thesis was to address this problem by means of an alternative approach for QD growth that utilizes metal-organic chemical vapor deposition on GaAs substrates patterned with inverted pyramidal recesses. The QDs obtained by this approach are referred to as site-controlled pyramidal QDs, and the technique for their growth has been refined in our research group since more than a decade. One of the principal achievements of this thesis was to develop a deterministic and scalable fabrication procedure for integrating InGaAs/GaAs pyramidal QDs into planar photonic crystal (PhC) cavities. In particular, we succeeded in coupling single QDs and pairs of spatially separated QDs with a three-hole defect (L3-type) PhC cavities. Owing to the excellent site control and the few-meV inhomogeneous broadening of pyramidal QDs, we could routinely obtain a spatial alignment precision of better than 50 nm and thereby yield many effectively coupled QD-cavity devices on the same substrate. This facilitated systematic examinations of the coupling characteristics of single and pairs of QDs in cavities, without ambiguities related to the QD positions and the possible presence of spectator QDs in the cavity region. First, we investigated the L3 cavities containing a single QD at their centers in micro-photoluminescence and photon correlation measurements. We observed that the QD exciton line closest to the cavity mode becomes markedly enhanced iii Acknowledgements in intensity upon crossing the resonance through temperature tuning, which is a characteristic signature of the Purcell effect in the weak coupling regime. Furthermore, we performed detailed polarization-resolved studies and found that the QD exciton becomes co-polarized to the cavity only within a narrow detuning range. Most notably, we also discovered that pyramidal QDs detuned by more than 5 meV could not couple their emission to the cavity, such that the cavity resonance was spectrally absent or neglig