4 research outputs found
Robust excitation of C-band quantum dots for quantum communication
Full text linkBuilding a quantum internet requires efficient and reliable quantum hardware,
from photonic sources to quantum repeaters and detectors, ideally operating at
telecommunication wavelengths. Thanks to their high brightness and
single-photon purity, quantum dot (QD) sources hold the promise to achieve high
communication rates for quantum-secured network applications. Furthermore, it
was recently shown that excitation schemes, such as longitudinal acoustic
phonon-assisted (LA) pumping, provide security benefits by scrambling the
coherence between the emitted photon-number states. In this work, we
investigate further advantages of LA-pumped quantum dots with emission in the
telecom C-band as a core hardware component of the quantum internet. We
experimentally demonstrate how varying the pump energy and spectral detuning
with respect to the excitonic transition can improve quantum-secured
communication rates and provide stable emission statistics regardless of
network-environment fluctuations. These findings have significant implications
for general implementations of QD single-photon sources in practical quantum
communication networks
Time-bin entanglement at telecom wavelengths from a hybrid photonic integrated circuit
Full text linkMass-deployable implementations for quantum communication require compact,
reliable, and low-cost hardware solutions for photon generation, control and
analysis. We present a fiber-pigtailed hybrid photonic circuit comprising
nonlinear waveguides for photon-pair generation and a polymer interposer
reaching 68dB of pump suppression and photon separation with >25dB polarization
extinction ratio. The optical stability of the hybrid assembly enhances the
quality of the entanglement, and the efficient background suppression and
photon routing further reduce accidental coincidences. We thus achieve a
96(-8,+3)% concurrence and a 96(-5,+2)% fidelity to a Bell state. The generated
telecom-wavelength, time-bin entangled photon pairs are ideally suited for
distributing Bell pairs over fiber networks with low dispersion
Single-active-element demultiplexed multi-photon source
No full textInternational audienceTemporal-to-spatial demultiplexing routes non-simultaneous events of the same spatial mode to distinct output trajectories. This technique has now been widely adopted because it gives access to higher-number multi-photon states when exploiting solid-state quantum emitters. However, implementations so far have required an always-increasing number of active elements, rapidly facing resource constraints. Here, we propose and demonstrate a demultiplexing approach that utilizes only a single active element for routing to, in principle, an arbitrary number of outputs. We employ our device in combination with a high-efficiency quantum dot based single-photon source, and measure up to eight demultiplexed highly indistinguishable single photons. We discuss the practical limitations of our approach, and describe in which conditions it can be used to demultiplex, e.g., tens of outputs. Our results thus provides a path for the preparation of resource-efficient larger-scale multi-photon sources
