Julia Neuwirth scite author profile

Quantum key distribution—exchanging a random secret key relying on a quantum mechanical resource—is the core feature of secure quantum networks. Entanglement-based protocols offer additional layers of security and scale favorably with quantum repeaters, but the stringent requirements set on the photon source have made their use situational so far. Semiconductor-based quantum emitters are a promising solution in this scenario, ensuring on-demand generation of near-unity-fidelity entangled photons with record-low multiphoton emission, the latter feature countering some of the best eavesdropping attacks. Here, we use a coherently driven quantum dot to experimentally demonstrate a modified Ekert quantum key distribution protocol with two quantum channel approaches: both a 250-m-long single-mode fiber and in free space, connecting two buildings within the campus of Sapienza University in Rome. Our field study highlights that quantum-dot entangled photon sources are ready to go beyond laboratory experiments, thus opening the way to real-life quantum communication.

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Optical properties of Pb_1-xMn_xTe

Neuwirth

Jantsch

Palmetshofer

et al. 1986

J. Phys. C: Solid State Phys.

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Quantum dot technology for quantum repeaters: from entangled photon generation toward the integration with quantum memories

Neuwirth

Basset

Rota

et al. 2021

Mater. Quantum. Technol.

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The realization of a functional quantum repeater is one of the major research goals in long-distance quantum communication. Among the different approaches that are being followed, the one relying on quantum memories interfaced with deterministic quantum emitters is considered as one of the most promising solutions. In this work, we focus on the hardware to implement memory-based quantum-repeater schemes that rely on semiconductor quantum dots for the generation of polarization entangled photons. Going through the most relevant figures of merit related to efficiency of the photon source, we select significant developments in fabrication, processing and tuning techniques aimed at combining high degree of entanglement with on-demand pair generation, with a special focus on the progress achieved in the representative case of the GaAs system. We proceed to offer a perspective on integration with quantum memories, both highlighting preliminary works on natural-artificial atomic interfaces and commenting a wide choice of currently available and potentially viable memory solutions in terms of wavelength, bandwidth and noise-requirements. To complete the overview, we also present recent implementations of entanglement-based quantum communication protocols with quantum dots and highlight the next challenges ahead for the implementation of practical quantum networks.

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Multipair-free source of entangled photons in the solid state

et al. 2022

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Daylight entanglement-based quantum key distribution with a quantum dot source

Basset

Valeri

Neuwirth

et al. 2023

Quantum Sci. Technol.

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Entanglement-based quantum key distribution can enable secure communication in trusted node-free networks and over long distances. Although implementations exist both in fiber and in free space, the latter approach is often considered challenging due to environmental factors. Here, we implement a quantum communication protocol during daytime for the first time using a quantum dot source. This technology presents advantages in terms of narrower spectral bandwidth—beneficial for filtering out sunlight—and negligible multiphoton emission at peak brightness. We demonstrate continuous operation over the course of three days, across an urban 270-m-long free-space optical link, under different light and weather conditions.

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Julia Neuwirth

Quantum key distribution with entangled photons generated on demand by a quantum dot

Optical properties of Pb_1-xMn_xTe

Quantum dot technology for quantum repeaters: from entangled photon generation toward the integration with quantum memories

Multipair-free source of entangled photons in the solid state

Daylight entanglement-based quantum key distribution with a quantum dot source

Contact Info

Product

Resources

About

Julia Neuwirth

Quantum key distribution with entangled photons generated on demand by a quantum dot

Optical properties of Pb1-xMnxTe

Quantum dot technology for quantum repeaters: from entangled photon generation toward the integration with quantum memories

Multipair-free source of entangled photons in the solid state

Daylight entanglement-based quantum key distribution with a quantum dot source

Contact Info

Product

Resources

About

Optical properties of Pb_1-xMn_xTe