A solid state source of photon triplets based on quantum dot molecules

TL;DR

This paper demonstrates a solid state quantum dot molecule that directly produces photon triplets with high rate, advancing multipartite quantum state generation for quantum information processing.

Contribution

It introduces a novel solid state source of photon triplets using coupled quantum dots, enabling efficient multipartite entanglement generation.

Findings

Achieved record photon triplet rate of 65.62 per minute.

Successfully generated correlated photon triplets via triexciton cascade.

Demonstrated potential for integrated quantum information applications.

Abstract

Producing advanced quantum states of light is a priority in quantum information technologies. While remarkable progress has been made on single photons and photon pairs, multipartite correlated photon states are usually produced in purely optical systems by post-selection or cascading, with extremely low efficiency and exponentially poor scaling. Multipartite states enable improved tests of the foundations of quantum mechanics as well as implementations of complex quantum optical networks and protocols. It would be favorable to directly generate these states using solid state systems, for better scaling, simpler handling, and the promise of reversible transfer of quantum information between stationary and flying qubits. Here we use the ground states of two optically active coupled quantum dots to directly produce photon triplets. The wavefunctions of photogenerated excitons localized in these ground states are correlated via molecular hybridization and Coulomb interactions. The formation of a triexciton leads to a triple cascade recombination and sequential emission of three photons with strong correlations. The quantum dot molecule is embedded in an epitaxially grown nanowire engineered for single-mode waveguiding and improved extraction efficiency at the emission wavelength. We record 65.62 photon triplets per minute, surpassing rates of all earlier reported sources, in spite of the moderate efficiency of our detectors. Our structure and data represent a breakthrough towards implementing multipartite photon entanglement and multi-qubit readout schemes in solid state devices, suitable for integrated quantum information processing.